A system and method of collecting energy utilizing a management system for an energy collection device, for collecting, managing, and discharging energy.

Abstract

A system and method of collecting energy utilizing a management system for an energy collection device, for collecting, managing, and discharging energy. Management system creates an active collection, storage, and discharging device; diffusion circuits allow for controlling the collecting, and discharging of harvested charges to precisely set requirements; the circuit allows for maximized charge collection over a given time, by minimizing the collection devices resistance to collection, the reduction in resistance is a factor calculated using the inverse square law, to allow ultra high speed maximized transitions in the charging, and discharging oscillation cycle.

Claims

1. A method of collecting, managing, and discharging energy comprising: at least one electrically conductive material exposed to different potentials of an electric field, and the electric field potentials causing charges to migrate by means of the conductive material; electrically connected to a managing device, in operation, the managing device controlling energy collection and discharge, including energy collection and storage, and energy storage discharge oscillation cycle frequency; and an electrical connection to a load.

2. The method of claim 1, wherein the device comprises, at least one of a bridge rectifier or solid state current controlling device, and additionally comprises at least one of, a collection array interface, a diffusion array interface; electrically connected to at least one of, the bridge rectifier, or solid state current controlling device, leads.

3. The method of claim 2, wherein at least one of, the collection array interface, or the diffusion array interface, or the collection array interface and the diffusion array interface, is electrically connected to the conductive material exposed to different potentials; wherein at least one of the bridge rectifier's negative lead, or solid state current controlling device negative lead, is, connected to a switch; and the bridge rectifier's positive lead, or the solid state current controlling device positive lead, is connected to a switch; or to the switch.

4. The method of claim 3, wherein the switches are electronic controlled solid state current controlling devices.

5. The method of claim 4, wherein the electronic controlled solid state current controlling devices are transistors electrically connected to one of the leads of a storage device; to charge the storage device, and constitute the charging portion and the first half of the oscillation cycle

6. The method of claim 3, wherein the switches are at least one of, a commutator, a reed switch, a reed relay, a solenoid, a relay; electrically connected to the leads of a storage device, each lead electrically isolated from the other lead; to charge the storage device, and constitute the charging portion and the first half of the oscillation cycle.

7. The method of claim 5, wherein the storage device is a capacitor.

8. The method of claim 6, wherein the storage device is a capacitor.

9. The method of claim 7, wherein the two leads of the capacitor are electrically connected to additional switches.

10. The method of claim 8, wherein the two leads of the capacitor are electrically connected to additional switches.

11. The method of claim 9, wherein the additional switches are electronic controlled solid state current controlling devices.

12. The method of claim 11, wherein the additional electronic controlled solid state current controlling devices are transistors electrically connected to the storage device; discharge through a load, or connect electrically to additional transistors, and capacitors for a combining discharge, and are the discharge part and second half of the oscillation cycle.

13. The method of claim 10, wherein the additional switches are at least one of, a commutator, a reed switch, a reed relay, a solenoid, a relay; and is electrically connected to the leads of a storage device electrically isolated from the other lead; discharge through a load, or connect electrically to additional storage devices for a combination discharge, and are the discharge part and second half of the oscillation cycle.

14. The method of claim 12, wherein a managing device controls functions consisting essentially of, the operation of all electronically operated components; diffusion circuits oscillation cycle frequency, and diffusion clusters oscillation cycles and combinational arrangements; power regulation means for regulating power; a memory section, a search starting means for starting a search; measurement data acquiring means for acquiring environmental data and electric power data, the environmental data being measured values of an environment surrounding the managing system; the electric power data representing information associated with electric power that is outputted from the energy collecting circuits, and the management system; deriving means for deriving a relational equation that holds between the environmental data and electric power data to maintain target values including voltage and current output; abnormal state determining means for determining whether or not the managing energy collecting device or any energy collecting circuits are in an abnormal state; and search procedure selecting means for selecting, in accordance with a result of determination of the abnormal state determining means, a procedure for managing abnormal energy collecting circuits or managing energy collecting device.

15. The method of claim 13, wherein a managing device controls functions consisting essentially of; operation of all electronically operated components; diffusion circuits, diffusion clusters combinational arrangements; power regulation means for regulating power; a memory section, a search starting means for starting a search; measurement data acquiring means for acquiring environmental data and electric power data, the environmental data being measured values of an environment surrounding the managing system, the electric power data representing information associated with electric power that is outputted from the energy collecting circuits, and the management system; deriving means for deriving a relational equation that holds between the environmental data and electric power data to maintain target values including voltage and current output; abnormal state determining means for determining whether or not the managing energy collecting device or any energy collecting circuits are in an abnormal state; and search procedure selecting means for selecting, in accordance with a result of determination of the abnormal state determining means, a procedure for managing abnormal energy collecting circuits or managing energy collecting device.

16. The method of claim 1 wherein, a rotary of collecting, managing, and discharging comprises essentially of, a rotary commutator switch, commutator brush assemblies, a commutator housing, with the commutator brush assemblies electrically connected to input and output leads of, a capacitors, and the positive and negative leads of, a bridge rectifiers; the bridge rectifiers additionally being connected to at least one of, the electrically conductive material exposed to different potentials of an electric field by means of the commutator brush assemblies; the commutator in operation, to control the oscillation frequency of charging the capacitors, and discharging the capacitors in prearranged configurations, by means of prearranged commutator bar configurations; the commutator rotating to operate a charge cycle, followed by a discharge cycle oscillation.

17. The method of claim 1, wherein the conductive material exposed to different potentials is a conductive tire, conductively coated, conductively impregnated or made of a conductive material.

18. The method of claim 1, wherein the conductive material exposed to different potentials, is interlocked with a charge carrier or conductive element, in a volumetric way, utilizing the useful energy collecting surface area to volume ratio of the device or support structure; arranging at least one of, the formation of materials, atoms, structures, surfaces, or utilizing unused surfaces, to create increased energy collecting surface area within a volumetric area.

19. A system of collecting, managing, and discharging energy comprising: a managing collection device; at least one electrically conductive material, exposed to different potentials of an electric field, electric field potentials causing charges to migrate by means of conductive material; electrically connected to a managing device, controlling energy collection and discharge, including energy collection and storage, and energy storage discharge oscillation cycle frequency, in operation; and a load electrically connected to at least one managing collection device.

20. The system of claim 19, wherein the device comprises, at least one of a bridge rectifier or solid state current controlling device, and additionally comprises at least one of; a collection array interface; a diffusion array interface, electrically connected to at least one of the bridge rectifier; or solid state current controlling device, leads.

21. The system of claim 20, wherein at least one of, the collection array interface, or the diffusion array interface, or the collection array interface and the diffusion array interface, is electrically connected to the conductive material exposed to different potentials; wherein at least one of the bridge rectifier's negative lead, or solid state current controlling device negative lead, is connected to a switch; and the bridge rectifier's positive lead, or the solid state current controlling device positive lead, is connected to a switch; or to the switch.

22. The system of claim 21, wherein the switches are electronic controlled solid state current controlling devices.

23. The system of claim 22, wherein the electronic controlled solid state current controlling devices are transistors, individually electrically connected to one of the leads of a storage device; to charge the storage device, and constitute the charging portion and the first half of the oscillation cycle.

24. The system of claim 21, wherein the switches are at least one of, a commutator, a reed switch, a reed relay, a solenoid, a relay; electrically connected to the leads of a storage device, each lead electrically isolated from the other lead; to charge the storage device, and constitute the charging portion and the first half of the oscillation cycle.

25. The system of claim 23, wherein the storage device is a capacitor.

26. The system of claim 24, wherein the storage device is a capacitor.

27. The system of claim 25, wherein the two leads of the capacitor are electrically connected to additional switches.

28. The system of claim 26, wherein the two leads of the capacitor are electrically connected to additional switches.

29. The system of claim 27, wherein the additional switches are electronic controlled solid state current controlling devices.

30. The system of claim 29, wherein the additional electronic controlled solid state current controlling devices are transistors electrically connected to the storage device; discharge through a load, or connect electrically to additional transistors and capacitor for a combining discharge, and are the discharge part and second half of the oscillation cycle.

31. The system of claim 28, wherein the additional switches are at least one of, a commutator, a reed switch, a reed relay, a solenoid, a relay; electrically connected to the leads of a storage device; electrically isolated from the other lead; discharge through a load, or connect electrically to additional storage devices for a combination discharge, and are the discharge part and second half of the oscillation cycle.

32. The system of claim 30, wherein a managing device controls functions consisting essentially of, the operation of all electronically operated components; diffusion circuits oscillation cycle frequency, diffusion clusters oscillation cycles and combinational arrangements; power regulation means for regulating power; a memory section, a search starting means for starting a search; measurement data acquiring means for acquiring environmental data and electric power data, the environmental data being measured values of an environment surrounding the managing system, the electric power data representing information associated with electric power that is outputted from the energy collecting circuits, and the management system; deriving means for deriving a relational equation that holds between the environmental data and electric power data to maintain target values including voltage and current output; abnormal state determining means for determining whether or not the managing energy collecting device or any energy collecting circuits are in an abnormal state; and search procedure selecting means for selecting, in accordance with a result of determination of the abnormal state determining means, a procedure for managing abnormal energy collecting circuits or managing energy collecting device.

33. The system of claim 31, wherein a managing device controls functions consisting essentially of, operation of all electronically operated components; diffusion circuits, diffusion clusters combinational arrangements; power regulation means for regulating power; a memory section, a search starting means for starting a search; measurement data acquiring means for acquiring environmental data and electric power data, the environmental data being measured values of an environment surrounding the managing system, the electric power data representing information associated with electric power that is outputted from the energy collecting circuits, and the management system; deriving means for deriving a relational equation that holds between the environmental data and electric power data to maintain target values including voltage and current output; abnormal state determining means for determining whether or not the managing energy collecting device or any energy collecting circuits are in an abnormal state; and search procedure selecting means for selecting, in accordance with a result of determination of the abnormal state determining means, a procedure for managing abnormal energy collecting circuits or managing energy collecting device.

34. The system of claim 19 wherein, a rotary collecting, managing, and discharging switch consists essentially of, a rotary commutator switch, a commutator brush assemblies, a commutator housing, with the commutator brush assemblies electrically connected to input and output leads of, a capacitors, and positive and negative leads of, a bridge rectifiers, with the bridge rectifiers additionally being connected to at least one of, the electrically conductive material exposed to different potentials of an electric field with commutator brush assemblies; the commutator in operation, to control the oscillation frequency of charging the capacitors, and discharging the capacitors in prearranged configurations, by means of prearranged commutator bar configurations; the commutator rotating to operate a charge cycle, followed by a discharge cycle oscillation.

35. The system of claim 19, wherein the conductive material exposed to different potentials is a conductive tire, conductively coated, conductively impregnated or made of a conductive material.

36. The system of claim 19, wherein the conductive material exposed to different potentials, is interlocked with a charge carrier or conductive element, in a volumetric way, utilizing the useful energy collecting surface area to volume ratio of the device or support structure; arranging at least one of, the formation of materials, atoms, structures, surfaces, or utilizing unused surfaces, to create increased energy collecting surface area within a volumetric area.

37. A system of collecting, managing, and discharging energy comprising: means for a collecting, means for managing, and means for discharging a collecting device; means of exposing at least one electrically conductive material to different potentials of an electric field, electric field potentials causing charges to migrate by means of conductive material, electrically connected to a managing device; and means for controlling energy collection and storage; means for controlling energy storage discharge; means for controlling energy collection, storage, and discharge oscillation cycle frequency.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0034] The invention will be described by reference to the detailed description of the preferred embodiment and to the drawings thereof in which:

[0035] FIG. 1 illustrates a preferred embodiment and the various operations of the management system.

[0036] FIG. 2 illustrates a simplified method of the management system, with the diffusion circuit.

[0037] FIG. 3 illustrates an embodiment of rotary management system.

[0038] FIG. 4 illustrates a commutator as the switching mechanism for a rotary management system.

[0039] FIG. 5 illustrates a commutator housing.

[0040] FIG. 6 illustrates a commutator brush assembly.

[0041] FIG. 7 illustrates a conductive tire and commutator assembly.

[0042] FIG. 8 illustrates an embodiment of a conductive charge collecting material, a conductive wire array, designed to be interlocked with a charge carrier element in a volumetric way.

DETAILED DESCRIPTION

[0043] Therefore, a heretofore, unaddressed need exists in the industry to address the aforementioned deficiencies and inadequacies.

[0044] Figures and embodiments contained are to demonstrate possible variations and to give a clearer understanding of the theory and method herein, to allow one with ordinary skill in the art to gain the ability to re-create said method.

[0045] The management system with reference to FIG. 1 is a functional block diagram schematically showing a configuration of the management system 1, it's diffusion circuit 2, it's power system section, it's central processing unit CPU 86, which includes the control section and the memory section.

[0046] Embodiments of the present disclosure can also be viewed as providing systems and methods for managing collecting energy, this can be briefly described in architecture one embodiment, among others, can be implemented by;

[0047] FIG. 1 illustrates the preferred embodiment of the system of managing collecting energy comprising, a circuit configuration controlling the collection and output of charges, controlled by the management system 1, hereinafter referred to as the diffusion circuit 2. Wherein exposed charge collecting conductive material located in an area of higher potential of charges hereinafter called collection array 30, for simplicity, uses conductive wires 20 elevated vertically into the atmosphere, which may be any conductive material, and exposed charge diffusing conductive material located in an area of lower potential of charges hereinafter called diffusion array 32, for simplicity uses conductive wires 20 grounded directly downward into the Earth, which may be any conductive material, are electrically connected to a bridge rectifier's 10 alternating current input AC leads, or a polarity, or potential charge separator, such as rectifying diodes, transistors 12, capacitors 14, vacuum tubes, solid state current controlling devices, avalanche diodes, solid-state semiconductors, liquid state semiconductors, with a bridge rectifier 10 being preferred.

[0048] This configuration allows a continuous migration of charges, this migration of charges causes a voltage differential or potential difference in the bridge rectifier's 10, positive and negative leads. Additionally, the bridge rectifier's 10, positive and negative leads are connected to an electronic switching device, in this case a transistor 12, which could be any number of different types or styles of transistors, thyristor, or layered semi-conductive material designed for electronically controlled switching, for each charging lead. Which then connect to the positive and negative leads of a capacitor 14, accumulator, or storage device, in a preferred embodiment of the method, a capacitor 14, is used to store a charge. The input and output of each capacitor 14, are then connected to separate output transistors 12, which could be any number of different types or styles of transistors, thyristor, or layered semi-conductive material designed for electronically controlled switching, with all transistors 12, controlled by a CPU 86, or microcontroller, embedded microprocessor, integral controller, derivative controller, system-on-a-chip, digital signal processor, transistor oscillation circuit, semiconductor oscillation circuit, silicone controlled rectifier, triac, field programmable gate array, or paired with an existing CPU 86, in a non-limiting example of a master and slave configuration of the management system 1. The CPU 86, is controlled by a computer code or script, embedded system, or artificial intelligence, that tells the system controller 84, to send a signal to the first set of transistors 12, to begin the charging of the capacitor 14, by activating the two transistors 12, connected to the positive and negative leads of the bridge rectifier 10, and creating a completed circuit, which is considered the first half of the oscillation cycle. The CPU 86, then sends a new instruction to the system controller 84, to send a signal to the second set of transistors 12, to begin discharging of the capacitor 14, and then arrange other capacitors in combinations, either in series or in parallel, which is considered the second half of the oscillation cycle.

[0049] This oscillation cycle can discharge through a load 72, or another storage device to create usable work, additionally the discharge cycle can be electrically connected to a transformer 56, that can modify the output current, and voltage if needed. The CPU 86, and system controller 84, then dictate the frequency of the charge and discharge cycle, and the combinations and arrangements of additional diffusion circuits 2, and diffusion clusters (multiple diffusion circuits), hereinafter referred to as circuit clusters 4, to gain the desired voltage level and total current output. Arrangements and oscillation frequency of capacitors 14, may include instantaneous oscillations, predetermined storage levels before oscillation, voltage measurement based storage discharge, continuous sampling and adjustment of current output, and additionally can be arranged to meet virtually any desired and defined frequency with available diffusion circuits 2, and diffusion clusters 4, this output can then be used to do desired work or for storage.

[0050] Each diffusion circuit 2, is an electrically connected system of components, and is managed by the management system 1, which may include additional devices and systems such as; a display 62, a direct current power conditioner 50, current power output interface 130, a pyrheliometer 34, pyrheliometer interface 114, a thermometer 36, a thermometer interface 116, a barometer 38, a barometer interface 118, voltmeter 40, voltmeter interface 120, an ammeter 42, an ammeter interface 122, a measuring device 44, a measuring device interface 140, an inverter 48, an inverter interface, a system controller 84, a system controller interface 124, power control means 46, power system interface 126, a target value setting capable device 54, a target value capable setting device interface 134, an input device 60, a target value interface 136, an alternating current output interface 58, a transformer 56, a variable frequency drive 52, a variable frequency drive interface 132, a central processing unit CPU 86, a processor 74, estimating means 76, computing means 78, network interface 138, load 72, search control means 80, relative relational expression equations 104, abnormal measurement memory 102, time series data memory 100, measurement data memory 98, accuracy data memory 96, operating estimations data 94, target value memory 92, a rated value database 90, collection array 30, collection array interface 110, diffusion array 32, diffusion array interface 112.

[0051] The control section serves to control the overall control and operation of various components of the management system 1, diffusion circuit 2, diffusion clusters, and the memory section serves to store information. The control section is configured to include a measurement data acquiring section (measurement data acquiring means), the amount of current/voltage (current/voltage acquiring means), a computing section (computing means), a target value setting section (target value setting means), a search control section (search starting means), power system section (power system controlling means), and in estimating section (estimating means). Further, the memory section is configured to include a target value memory section, a memory section, and a relative relational expression equation section, a rated value database.

[0052] The memory section serves to store, as measurement data 98, measurement data obtained from each measuring instrument while the management system 1, is operating. Specifically, the measurement data contains the following measured values measured at the; measure point of time, operating current value, operating voltage value, amount, and temperature, atmospheric pressure, solar radiation. The measure point in time is data representing year, month, day, hour, minute, and second. Further, the operating current value in operating voltage value refer to values of an electric current and voltage is measured at a point, respectively.

[0053] Further, solar radiation, temperature, and atmospheric pressure is measured by the pyrheliometer 34, thermometer 36, or the barometer 38, respectively. The rated value database 90, is provided with a memory section and a target value memory section. The memory section serves to store relative relational expression equations 104, for maintaining operating current values and operating voltage values. The target value memory 92 section, serves to store target values of the operational estimations 94, and accuracy of relative relational expression equations 96, that can be interpreted for command allocation.

[0054] The measurement data 98 acquiring section, serves to acquire measuring values from each measurement instrument. Specifically, the measurement data acquiring section acquires measurement data 98 of (electrical power data, environmental data), which is time-series data 100, containing the electric current value, the voltage value, the temperature, the atmospheric pressure, from the measuring instruments of the ammeter 42 and voltmeter 40, the pyrheliometer 34, thermometer 36, and barometer 38, and sends the measurement data to the search control section 80 of the database.

[0055] The search control section 80, searches for relative relational expression equations 104, to interpret historical relations to measurement values 98, and interpret proportional relationships between stored measurement values 98, operational characteristics 94, and predetermined target value 98 ranges, including output characteristics, discharge cycle relational information including combinational arrangement output power data, cluster combination data, and duty cycle optimization equations.

[0056] The search control section 80, can compute measurement characteristics if measurements have been measured and stored even once and can compare characteristics with the target value setting section 92, which may also incorporate a learning effect, or artificial intelligence, interpretations can be interpreted by the central processing unit CPU 86, which can send instructions to the system controller 84, which can then send command signals to active switching and control systems, and components, to control predetermined, or instructed operational target values and functions.

[0057] The measurement data acquiring 96 section, also serves to determine faults, by acquiring and comparing measured values from the measurement data memory 98 storage section, and by interpreting operating system abnormal measurements 102. Abnormal measurements 102, are stored in the memory storage section, and additionally may be sent to the display 62, to indicate to users of the management system 1, abnormal measurements 102, or sent to the control section and the target value memory section 92, to perform tasks such as bypassing abnormally operating diffusion circuits 2, diffusion clusters 4, systems, or component's, or by compartmentalizing systems containing faults and maintaining predetermined target operating conditions, charging and discharging cycles, output power characteristics and functions.

[0058] It should be noted that measurements may be computed by performing measurements by measuring each instrument once, or more than once, at a time of introduction of the management system 1, or may be computed as a search performed manually by the user's operating the management system 1, or maybe performed automatically, e.g., regularly. In particular measurements may be performed at predetermined intervals, or from time to time.

[0059] FIG. 2 illustrates an exemplified embodiment of the management system 1 comprising, a diffusion circuit 2 configuration and system controller 84, controlling the collection and output of charges, controlled by the system controller of the management system 1, hereinafter referred to as the diffusion circuit 2. Wherein exposed charge collecting conductive material located in an area of higher potential of charges hereinafter called collection array 30, for simplicity, uses conductive wires 20 elevated vertically into the atmosphere, which may be any conductive material, and exposed charge diffusing conductive material located in an area of lower potential of charges hereinafter called diffusion array 32, for simplicity uses conductive wires 20 grounded directly downward into the Earth, which may be any conductive material, are electrically connected to a bridge rectifier's 10 alternating current input leads, or polarity, or potential charge separator, such as rectifying diodes, transistors 12, capacitors 14, vacuum tubes, solid state current controlling devices, avalanche diodes, solid-state semiconductors, liquid state semiconductors, with a bridge rectifier 10 being preferred.

[0060] This configuration allows a continuous migration of charges, this migration of charges causes a voltage differential or potential difference in the bridge rectifier's 10, positive and negative leads. Additionally, the bridge rectifier's 10, positive and negative leads are connected to an electronic switching device, in this case a transistor 12, which could be any number of different types or styles of transistors, thyristor, or layered semi-conductive material designed for electronically controlled switching, for each charging lead. Which are then connect to the positive and negative leads of a capacitor 14, accumulator or storage device, in a preferred embodiment of the method, a capacitor 14, is used to store a charge. The input and output of each capacitor 14, are then connected to separate output transistors 12, which could be any number of different types or styles of transistors, thyristor, or layered semi-conductive material designed for electronically controlled switching, with all transistors 12, controlled by a system controller 84 or microcontroller, embedded microprocessor, integral controller, derivative controller, system-on-a-chip, digital signal processor, transistor oscillation circuit, semiconductor oscillation circuit, silicone controlled rectifier, triac, field programmable gate array, or paired with an existing CPU, in a non-limiting example of a master and slave configuration of the management system 1. The system controller 84, is controlled by a computer code or script, embedded system, or artificial intelligence, that tells the system controller 84, to send a signal to the first set of transistors 12, to begin the charging of the capacitor 14, by activating the two transistors 12, connected to the positive and negative leads of the bridge rectifier 10, and creating a completed circuit, which is considered the first half of the oscillation cycle. The CPU 86, then sends a new instruction to the system controller 84, to send a signal to the second set of transistors 12, to begin discharging of the capacitor 14, and arrange them in combinations, either in series or in parallel, which is considered the second half of the oscillation cycle.

[0061] This oscillation cycle can discharge through a load 72, or another storage device to create usable work, additionally, the discharge cycle can be electrically connected to a transformer 56, that can modify the output current, and voltage if needed. The system controller 84, then dictates the frequency of the charge and discharge cycle, and the combinations and arrangements of additional diffusion circuits 2, and diffusion clusters 4, to combine the capacitor(s) 14, outputs in series, and in parallel groups, to gain the desired voltage level and total current output. Arrangements and oscillation frequency of capacitor(s) 14, may include instantaneous oscillations, predetermined storage levels before oscillation, voltage measurement based storage discharge, continuous sampling and adjustment of current output, and additionally can be arranged to meet virtually any desired and defined frequency with available diffusion circuits 2, and diffusion clusters 4, this output can then be used to do desired work or for storage.

[0062] The benefit to this simpler system is it can be used in a wide variety of applications, including electronics, electronic devices, electrical equipment, lighting, vehicles and transportation and virtually all devices requiring operational power. The advantage being the ability of using embedded circuitry reducing the physical size and cost each diffusion circuit 2, and diffusion cluster 4, which can be especially advantageous with electronic devices, lights, computers, tablets, cell phones, media players, watches, small motorized devices such as skateboards, hover boards, mopeds, motorized bikes, jet packs, water propulsion devices, radios, streetlights, flashlights, signs, information display screens, remote electronic equipment, and both permanent and non-permanent electronic devices, and other smaller less power consuming devices. Also, a human can act as a conductive material for charge collecting, the human conductor is standing on an insulating surface which maybe insulating shoes or other similar wearable coverings or insulating surfaces, making contact through it's conductive body with a collection array interface 112, in other embodiments the conductive contact could be built into devices, such as wearable technologies, smart glasses, headsets, earphones that act as the collection array 30.

[0063] FIG. 3 illustrates an embodiment of rotary mechanical management system 82, hereinafter referred to as rotary diffusion circuit 6, that may also utilize a hybrid mechanical-electronic management system, as described herein. As the vehicle begins to drive, the charge collection radiator 160, is bombarded with electric charges that create a higher voltage potential in the charge collection radiator 160, the charges then migrate through an electrical connection into the full wave bridge rectifier 10 Alternating Current AC lead, and out the other AC lead on the full wave bridge rectifier 10, which is electrically connected to a hanging tether that makes a ground connection, or to a commutator that makes an electrical connection to the vehicle's tire 220, that has been made to be conductive or impregnated with conductive material 224, 236, 242.

[0064] The positive and negative leads on the full wave bridge rectifier 10, are electrically connected to commutator brush assemblies 192 mounted in the commutator brush housing 188. As the charges migrate they create a voltage differential, and potential difference is between the positive and negative leads of the full wave bridge rectifier 10; which makes contact through the commutator brush assemblies 192, the brushes 192, through the commutator 150, to the capacitor input line 172, and capacitor output line 174, to charge the capacitor(s) 14.

[0065] The bridge rectifier positive and negative leads connected to commutator brush assemblies 192, are controlled by a rotating commutator 150, that contact commutator bars. As the commutator 150 rotates, the commutator brush assemblies 192, make contact with alternating commutator bar configurations, one commutator bar configuration connects the leads of the capacitor 14, to the positive and negative leads of the full wave bridge rectifier 10, which charges the capacitor 14, this could be considered the first half of the oscillation cycle. The capacitor 14, then switches into a commutator bar discharge configuration as the commutator rotates, through the commutator brush assemblies 192, discharging the capacitor(s) in series and in parallel, through the commutator slip ring output 170, and commutator slip ring input 168, to gain a usable voltage, and complete a circuit, which can be considered the second half of the oscillation cycle. This output can then be routed through a power system 84, for voltage and current regulation, and into a load 72, or another storage device to create usable work.

[0066] This embodiment of a mechanical rotary management system 82, has the advantage that it can be installed to not require an input current to create the output current. In an embodiment, it is installed on an electric vehicle and uses forced atmospheric triboelectric diffusion, that forces air across the radiator 160 that acts as the conductive collecting material with a higher potential, and is electrically connected to the rotary mechanical management system 82, that is coupled to a spinning mechanical component like a vehicle drive shaft.

[0067] Each rotary diffusion circuit 6, can have a specific calculated oscillation cycle or be combined with and electronic management system (not shown) to control, and adjust the voltage, and current output, of the entire unit, which may consist of tens, hundreds, thousands, millions or even more individual rotary diffusion circuit's 6. Additionally, the electronic management system (not shown) can regulate and stabilize the output characteristics of the discharge cycle, which be greatly beneficial used in for instance an electric car, vehicle, plain or other aircraft, helicopters, flying cars, jets, or spaceships, to provide a stable input power the battery, to increase it's life expectancy and robustness and capacity.

[0068] The commutator 150, rotation, mechanical device switching speed, or the transistor(s) (not shown), inputs and outputs, or another mechanical device such as a relay, thyristor, or layered semi-conductive material designed for electronically controlled switching, with all transistors (not shown), controlled by a system or paired with an existing CPU, controller or microcontroller, embedded microprocessor, integral controller, derivative controller, system-on-a-chip, digital signal processor, transistor oscillation circuit, semiconductor oscillation circuit, silicone controlled rectifier, triac, field programmable gate array, or paired with an existing CPU, in a non-limiting example of a master and slave configuration of the management system 1, which may additionally be controlled by a microprocessor, or microcontroller or embedded CPU controlled by a computer code or script, embedded system, or a non-limiting example of a master and slave configuration, controlled by the management system 1, which then dictates the frequency of the charge and discharge cycle and are arranged to combine the capacitor(s) 14, in series, and or in parallel, to gain the desired voltage level and total current output.

[0069] Rotary diffusion circuits 6, can be multiplied, with multiple bridge rectifier 10, or solid state current controlling devices, transistor (not shown), diode, vacuum tube cathode, and capacitor 14 systems, or combinations, which can and then combined, in both series and or parallel for discharging.

[0070] Additionally other areas of a vehicle may have conductive attributes, the vehicle may be coated with conductive paint, the windows may be conductively coated, and the fabric in the vehicle may be conductive, the interior may be conductively coated, the vehicles frame may be conductive, the vehicle may have conductive siding or conductive paint which could all be used to increase the amount of charge migration and as well the amount of charges able to be collected, and act as collection materials.

[0071] Another embodiment of this management system and method is implemented to benefit existing power production units by allowing charges to travel out of the generating unit at a lower voltage potential. When charges build up inside a generator unit they create a magnetic field, this magnetic field pushes back on the prime mover of the generator unit, causing an increased amount of workload. This pushing back force is called back electromagnetic, or electromotive force. Utilizing this management system, a generator can output current in the mili and micro volts and amps, by having the discharge of current at a lower potential will cause the generating unit to operate with less workload, making the unit more efficient. Since the majority of current generating units are built on heat exchange systems, less fuel will be required to operate the generating units in the benefit to this is self-explanatory.

[0072] FIG. 4 illustrates a diagram showing a rotary commutator unit 150, as part of the rotary mechanical management system 1, commutator 150, connects to a rotating mechanical part via it's coupling channel 154, and is held in place by the commutator fastener ports 184, and fasteners (not shown). As the commutator rotates the collector input bar 178 and the collector output bar 180 form a circuit with the capacitor (not shown), via commutator brush assemblies (not shown), this circuit is the first half of the oscillation cycle. As the commutator rotates the commutator brush assemblies (not shown) rotate to the next set of commutator bars which are the capacitor input line 172, and the capacitor output line 174, separated from the collector input bar 178, and the collector output bar 180 by commutator slots 176. This is the second half of the oscillation cycle, and all of the capacitors (not shown) then connect via the discharge series commutator connector bars 182, to complete the circuit with a load (not shown) via the commutator slip ring input 168, and commutator slip ring output 170, to complete the oscillation and charge discharge cycle. Though this embodiment is a rotational management system a linear system is also possible as long as a consistent linear motion exists, this would therefore mean that the alternating commutator bar set up would be configured in a linear fashion.

[0073] FIG. 5 is an illustration of the commutator housing unit 152, that is held in place by the mounting brackets 186 this is mounted around a commutator (not shown) in the commutator chamber 154, this is another component of the rotary switching system 82, which is designed to hold the commutator brush assemblies (not shown), and the commutator brush housing's 188, the commutator brush assemblies (not shown) are held in place with fasteners (not shown) in the fastener ports 190.

[0074] FIG. 6 is an illustration of the commutator brush assembly 192, which consists of the commutator brush 196, the commutator spring 194, the conductive wire 20, and the fastener ports 190 for the fasteners (not shown).

[0075] FIG. 7 is an illustration of the conductive tire 220, it consists of conductive material contacting the ground via conductive studs 236, a conductive strip along the tire 224, or the tire made of a conductive material 242, the tire can make direct contact with the frame with it's direct frame contact 232, or it can make contact as part of the rotary management system (not shown), via a commutator unit comprising mainly of commutator mounting bracket 240, the commutator housing 238, the commutator spring and wire assembly 234, a commutator brush to 228, and a tire commutator slip ring 230, this unit could be considered the conductive array with lower potential or defusing array 32.

[0076] FIG. 8 illustrates a diagram showing wire as the conductor with higher potential deployed volumetrically area as the collection array 30, conductive wire 20, is a fixed to insulating array frame 200, the insulating structure 202, and conductive wire, may alternately, be in the form of a microscopic circuit path (not shown) as in a microprocessor (not shown), in this embodiment it may be possible to have thousands of kilometres of conductive wire or paths, and millions of diode (not shown) or transistor (not shown) connections, such as in a microprocessor that may have hundreds of millions or billions of transistors present, and an insulating surface, which may consist of multiple insulating surfaces, as in a microprocessor (not shown). Insulating array frame 200, which may also be an insulating container (not shown), support the insulating wire support surface 208, positive charges collected through conductive wire 20, and travel through the conductive wire conduit 206, and out the collection interface 110, the conductive wire 20 is held in place with conductive wire mounting brackets 210.

[0077] The collection array 30, and diffusion array 32, uses conductive materials, and structures to greatly increase the surface area of a collection device, by continuously interlocking it with a conductive or charge carrier element, in a volumetric way, and creating structures within the volumetric area that can interlock with conductive or charge carrier elements, so as to maximize the interlocked surface area of the element and the arrays, for greater electromagnetic diffusion. Embodiments may consist of small microscopic solid segmented surfaces or conducting sheets, in a volumetric area less than a few square feet, or square inches or smaller, interlocked with a conductive element. The surface area is greatly expanded by sectioning the solid conductive material into conducting sheets. The conductive sheets are held and separated by insulating mounts, insulating mounts may be a semi-conductive material allowing for dual-purpose structural and current path, and are arranged on an insulating surface, which may also be a conductive contact point in which a human, or animal, or other conductive body makes contact with the device in order to greatly expand the volumetric energy collecting surface area.

[0078] The collection array 30, and diffusion array 32, are preferred to be made out of a low resistance conductive material such as carbon (graphene), silver, copper, annealed copper, gold, aluminum, calcium, tungsten, zinc, nickel, lithium, iron, platinum, tin, carbon steel, led, titanium, grain oriented electrical steel, manganin, constantan, stainless steel, mercury, nichrome, gaAs, carbon (amorphous), carbon (graphite), germanium, silicone, wood (damp), teflon, with the best results so far having been attained from pure copper.

[0079] In order to allow charges to flow the surfaces and structures need to be of electrically conductive material, which may be a paint or coating, and could be made from any microscopic, or not microscopic, open cells structures, or closed cells structures, or solid structures, or surfaces. Segmented surfaces may also be used, conductive gas, conductive particles, conductive particles suspended in liquid, conductive particles suspended in matter, or conductive particles suspended in gas. Conductive paint is an example of conductive particles suspended in a liquid that turns to a solid, as well as conductive sealant is also an example of a conductive particles suspended in a liquid that once it evaporates it turns into a solid. With the advancements in technology Conductive filament may be very advantageous to use in some circumstances. Non-metal conductive matter or non-conductive materials conductively plated can also be a good substitute, they may be conductively coated as well, or impregnated with conductive material.

[0080] Array options may also include magnetic or non-magnetic substances selected from the group consisting of metals, semi-metals, alloys, intrinsic or doped, inorganic or organic, semi-conductors. Other materials may include dielectric materials, layered materials, intrinsic or doped polymers, conducting polymers, ceramics, oxides, metal oxides, salts, organic molecules, cements, and glass and silicate which if made to allow the transfer of charges, or the conducting of charges could provide potential substitutes.

[0081] As well, a conductive structure may comprise a vast variety of options for a collection array 30, these may include a building and all of it's interior or exterior surfaces, which include roofs, walls, windows, ceilings, window frames, gutters, siding, insulation, drywall, fencing, furniture, flooring, doors, ducting, drapes, couch's, desks, tables, ottomans, shelving, beds, chairs, carpet, and may also include wire, electronic casings, rods, beams, or it's frame. Particles, gases, liquids, sheets, foil and meshes may also be support structures. Human and animals as well as clothing could also be used as long as they are made to be conductive.

[0082] Vehicles may also be used as a collection array 30, and could include, airplanes, helicopters, flying cars, jets, rockets, spaceships, satellites, cars, trucks, vans, motorcycles, dump trucks, hauling trucks, blimps. Other support structures may include concrete, asphalt, roadways, bridges, overpasses, runways, train yards, wind turbines, solar panels, cell towers, radio towers, sails, drilling rigs, towers, masts, mobile buildings, platforms, billboards, water towers, skyscrapers, coliseums, roller coasters, hangers, cranes, arrays, space stations, living habitats, expandable arrays, conductively 3d printed structures, green houses, silos, exhaust stacks, a fixed or mobile structure, planets, moons, earth, and the ground, if made to be conductive.

[0083] The present invention is not limited to the description of the embodiments provided but may be altered by skilled person within the scope of the claims. An embodiment based on the proper combination of technical means disclose in different embodiments is encompassed in the technical scope of the present invention.

[0084] The blocks or, in particular, the control section of each of the diffusing circuits or the management system may be achieved through hardware logic or through software by using a CPU 86 as described. That is each management system and diffusing circuit 2, includes a CPU 86 central processing unit, which executes instructions from a program for achieving the corresponding function; a ROM read-only memory, in which the program is stored; a ram random access memory, to which a program is loaded; a memory device recording medium such as memory, which the program various types of data are stored; and the like.

[0085] Moreover, the object of the present invention can be attained by mounting, to each of the diffusing circuits 2, a recording medium computer readably containing a program code to execute form program, intermediate code program, source program of software for achieving the offer mentioned function, in order for the computer CPU 86 or MPU memory processing 74 unit to retrieve and execute the program code recorded in the recording medium, through a non-limiting example of a system controller. Examples of the recording medium encompass: tapes, such as magnetic tapes and cassette tapes; discs include magnetic disk, such as floppy disks, and hard disks, flash drives, SD cards, and optional desks, such as a CD-ROM's, MO's, MDs, BBs, DVDs, and CD-Rs; cards, such as icy cards including memory cards and optical cards; and semiconductor memories, such as masks ROM's, EEPROM's, EEPROM's, and flash ROM's.

[0086] Further each of the management systems can be made connectable to a communications network so the program code can be supplied via the communications network. Examples of the communications network can include, but are not limited particularly to, the Internet, and intranet, and extranet, a LAN, ISDN, a VAN, a CATV communication network is not particularly limited. For example it is possible to use, as a transmission medium, a cable such as a IEEE1394, a USB, a power line, a cable TV like, a telephone line, an ADSL line, etc. alternatively, it is possible to use, as a transmission medium, a wireless system such as infrared rays as inIrDA and a remote controller, Bluetooth, 802.11 wireless, HDR, cellular phone network, satellite line, a terrestrial digital network, etc. it should be noted that the present invention can be achieved in the form of a computer data signal realized by electronic transmission of the program code and embedded in a carrier wave.

[0087] Further, the present invention can be expressed as follows: a management system according to the present invention is a management system for managing collecting energy, the management system being configured to include: a control means to control the overall control and operation of various components of the management system 1, a diffusion circuit charge collecting means for collecting charges from a diffusion circuit, potential differential creating means for creating a potential difference, a memory storage means to store information in memory, amount of solar radiation/temperature/atmospheric pressure acquiring means for acquiring an amount of solar radiation and/or temperature and/or atmospheric pressure; current/voltage acquiring means for acquiring an electric current value and/or voltage value, a computing section computing means to compute information and instructions, a target value setting means to set target values, search starting means to control searching, power system controlling means to control power system functions, estimating means to preform estimations, searching means for searching memory deriving means for deriving relational expression equations. Further, the memory section is configured to include a target value memory section, a memory section, and a relative relational expression equation section, a rated value database.

[0088] Further, the method according to the present invention for an managing system, is a control method for the management, and for controlling energy collection and output and characteristics, the method including, a target value setting input step, an oscillation frequency setting step, making a connection to a conductive material with a potential difference step, an activating charging circuit switches step, a collecting charges from a diffusion circuit step, a storing collected charges step, a deactivating charging circuit step, an activating output circuit with stored charges step, a step combining stored charges in series and parallel, a step of acquiring an electric current value and/or voltage value, an amount of solar radiation/temperature/atmospheric pressure acquiring step, a step of recording acquired information in the rated value database memory in appropriate sections, a step of computing and interpreting information based of recorded memory data, a step of forming instructions to send to system controller based on recorded memory data, set target values, and their relational effects to stored and discharged charges, a step of communicating information to the system controller for task execution based on the interpreted and set target values, a step of outputting power through a load based on set target values, relational estimations, and inputted commands.

[0089] The foregoing was intended as a broad summary only and only of some of the aspects of the invention. It was not intended to define the limits or requirements of the invention. Other aspects of the invention will be appreciated to one skilled in the art by reference to the detailed description of the preferred embodiment and to the claims. It is intended that all such additional systems, methods, aspects, and advantages be included with this description, and within the scope of the present disclosure, and be protected by the accompanying claims.

[0090] The terms used in this disclosure are not for limiting the inventive concept but for explaining the embodiments. The terms of a singular form may include plural forms unless otherwise specified. Also, the meaning of include, comprise, including, or comprising, specifies a property, a region, a fixed number, a step, a process, an element and/or a component but does not exclude other properties, regions, fixed numbers, steps, processes, elements and/or components. The reference numerals presented according to a sequence of explanations are not limited to the sequence.

[0091] In addition, some embodiments of the present disclosure may include patents or public disclosures already issued relating to this art, when used in conjunction with this system or method these prior schemes may be able to generate substantial amounts of usable power. By using the described system and method many of these previously failed schemes and inventions may be able to harvest enough continuous power to be potentially commercially viable, and when referring to these said inventions or schemes when combined with this disclosed system or method these devices should be considered new devices or improvements thereof and confer the protection of this disclosure, or future patent, this does not limit the scope of the present disclosure instead giving reference to where some embodiments of this discovery may fit into the art.