Supplemental electrical power generating system

US 4,262,209 A
Filed: 02/26/1979
Issued: 04/14/1981
Est. Priority Date: 02/26/1979
Status: Expired due to Term

First Claim

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1. An energy conversion system for independently supplying demand-controlled supplemental AC electrical power continuously upon demand to an electrical load in electrical phase synchronism with, simultaneously with, and in parallel with an operating, existing source of AC electrical power, said system comprising commutator AC generator means operating at an controllably variable shaft speed unrelated to the frequency of said existing source of AC electrical power, a prime mover for operating said commutator AC generator means, said prime mover being controllable to vary the magnitude of the available mechanical shaft power thereof to produce a controllably variable shaft speed of said commutator AC generator means which shaft speed is unrelated to the frequency of said existing source of AC electrical power, said commutator AC generator means being adapted to generate supplemental AC power for delivery to said electrical load for satisfying AC power requirements of said electrical load, exciter means for exciting said commutator AC generator means proportional to the magnitude of in-phase real power demand of said electrical load regardless of the controllably variable shaft speed of said commutator AC generator means, electrical load current demand sensor means, independent from said operating, existing source of AC power, for providing a demand control signal which is proportional to the magnitude of in-phase real power demand of said electrical load, first control means interconnected with said prime mover for controlling the production of available mechanical shaft power by said prime mover in proportion to the magnitude of in-phase real power demand of said electrical load, and second control means interconnected with said exciter means for controlling the degree of excitation of said commutator AC generator means to cause the electrical power output thereof to substantially meet and be continually responsive to the magnitude of in-phase real power demand of said electrical load regardless of the mechanical shaft power produced by said prime mover and regardless of the controllably variable shaft speed of said commutator AC generator means.

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Abstract

Hydrocarbon fuel energy is converted to AC electrical energy by a new system utilized to supplement AC power for household and similar limited size loads in synchronism with existing AC utility service via pre-existing wiring between the load and the utility lines. The system has an externally excited commutator AC motor-generator driven by an internal combustion engine to provide AC power at a magnitude which is a function of the drive shaft velocity and degree of excitation. An exciter circuit provides excitation for the motor-generator to cause the generated AC power to be in phase with utility power. A load demand sensor senses current flowing through the wiring to the load, providing a control signal signifying magnitude of the current, thus measuring load power requirements. Control circuitry interconnected with the exciter circuitry and the engine is responsive to the control signal to control excitation for causing the generated supplemental power substantially to meet load requirements. The control circuitry also controls engine speed to provide sufficient engine power to meet these load requirements. Mechanical elements of the system are contained by an insulated, sound-proofed enclosure. Air is drawn into the enclosure for cooling of the motor-generator and for recovering heat from the engine and the engine exhaust. The heated air is ducted out of the housing for use in household heating, etc. Various circuit features, including a phase sensitive detector, ensure that electrical power generated by the system does not flow back to the utility service. The system starts and stops automatically according to power demand.

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21 Claims

1. An energy conversion system for independently supplying demand-controlled supplemental AC electrical power continuously upon demand to an electrical load in electrical phase synchronism with, simultaneously with, and in parallel with an operating, existing source of AC electrical power, said system comprising commutator AC generator means operating at an controllably variable shaft speed unrelated to the frequency of said existing source of AC electrical power, a prime mover for operating said commutator AC generator means, said prime mover being controllable to vary the magnitude of the available mechanical shaft power thereof to produce a controllably variable shaft speed of said commutator AC generator means which shaft speed is unrelated to the frequency of said existing source of AC electrical power, said commutator AC generator means being adapted to generate supplemental AC power for delivery to said electrical load for satisfying AC power requirements of said electrical load, exciter means for exciting said commutator AC generator means proportional to the magnitude of in-phase real power demand of said electrical load regardless of the controllably variable shaft speed of said commutator AC generator means, electrical load current demand sensor means, independent from said operating, existing source of AC power, for providing a demand control signal which is proportional to the magnitude of in-phase real power demand of said electrical load, first control means interconnected with said prime mover for controlling the production of available mechanical shaft power by said prime mover in proportion to the magnitude of in-phase real power demand of said electrical load, and second control means interconnected with said exciter means for controlling the degree of excitation of said commutator AC generator means to cause the electrical power output thereof to substantially meet and be continually responsive to the magnitude of in-phase real power demand of said electrical load regardless of the mechanical shaft power produced by said prime mover and regardless of the controllably variable shaft speed of said commutator AC generator means.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20)
- - 2. An energy conversion system as defined in claim 1, said first control means operating continuously to cause variation in the production of available shaft power by said prime mover for producing corresponding variation in shaft speed of said commutator AC generator means, whereby said shaft speed is adequate for providing mechanical energy sufficient for said commutator AC generator means continuously to satisfy power requirements of said electrical load as said requirements may vary.
  - 3. An energy conversion system as defined in claim 2, said shaft speed being subject to substantial variation and being entirely independent of conventional AC generator synchronous speed.
  - 4. An energy conversion system as defined in claim 3 wherein said commutator AC generator means has a shaft speed substantially greater than said synchronous speed whereby said generator means requires a minimum of electrical winding materials and reduced amounts of magnetic core material.
  - 5. An energy conversion system as defined in claim 1 wherein said system is autonomous from said existing source of AC electrical energy.
  - 6. An energy conversion system as defined in claim 1 and further comprising means for automatically limiting said first and second control means to prevent further increase is available mechanical shaft power provided by said prime mover and to prevent further increase in the generation of supplemental AC power by said commutator AC generator means, whereby AC electrical power requirements of said electrical load in excess of a predetermined maximum produced by said system are provided by said existing source of AC electrical power.
  - 7. An energy conversion system as defined in claim 1, said system, said existing source of AC electrical energy, and said electrical load all being connected to a single node, said existing source comprising a commercial AC electrical utility service line.
  - 8. An energy conversion system as defined in claim 7 and further comprising abnormal voltage sensing means for sensing voltage at said node for terminating operation of said voltage if said voltage is abnormal.
  - 9. An energy conversion system as defined in claim 1 and further comprising load demand threshold means for initiating operation of said system upon the AC power requirements of said electrical load exceeding a predetermined threshold.
  - 10. An energy conversion system as defined in claim 9 wherein said prime mover is an internal combustion engine and further comprising means, responsive to said load demand threshold means, for initiating starting of said engine upon said AC power requirements exceeding said predetermined threshold.
  - 11. An energy conversion system as defined in claim 10 wherein said means for initiating starting is operative to cause said commutator AC generator means to operate as a motor initially for starting said engine, and further comprising means for causing said commutator AC generator means to revert to generation of supplemental AC power for delivery to said electrical load upon said engine reaching a predetermined speed.
  - 12. An energy conversion system as defined in claim 10 and further comprising means for causing re-initiation of starting of said engine if said engine fails to reach a predetermined speed within a time delay interval.
  - 13. An energy conversion system as defined in claim 1 and further comprising power distribution means interconnecting said load and said existing source of AC electrical energy, and phase sensitive detector means operatively associated with said power distribution means for sensing voltage-current phase relationship of AC electrical energy supplied from said existing source to said load, said phase sensitive detector means being operative for controlling said exciter means in a sense for preventing flow of electrical power from said system to said existing source.
  - 14. An energy conversion system as defined in claim 13, said system, said existing source of AC electrical energy, and said electrical load all being connected to a single node, said system comprising a power distribution cable interconnecting said node and said existing source of AC electrical energy, said phase sensitive detector having voltage reference and current inputs, said node providing said voltage reference input, and a current transformer associated with said power lead for sensing current flowing between said existing source of AC electrical energy and said node, said current transformer providing said current input.
  - 15. An energy conversion system as defined in claim 1, said existing source of AC electrical energy being interconnected with said load by a power distribution cable, said electrical load demand sensor means comprising a current transformer having a flexible, pliable core of flexible, threadlike ferromagnetic strands which can be shaped to fit through a confined, irregularly shaped access space around said cable without need to disturb or disconnect said cable during installation of said core, said core surrounding said cable, said cable constituting a single turn primary winding, said transformer having a secondary winding having numerous turns wound around said core and providing a voltage proportional to the magnitude of current passing through said cable.
  - 16. An energy conversion system as defined in claim 1 and further comprising means for recovering thermal energy expended in the operation of said system and for providing flow of heated air from said system for utilization of said recovered thermal energy, including means for directing air for cooling of said commutator AC generator means, a fan for causing movement of said air, and means for ducting said air from said system, said air being heated by cooling of said commutator AC generator means.
  - 17. An energy conversion system as defined in claim 16, said means for recovering thermal energy further including an enclosure for enclosing at least said commutator AC generator means, said enclosure providing thermal isolation from the environment external to said system, said air being drawn into said enclosure for cooling of said commutator AC generator means by said fan, said air being directed out of said enclosure after being heated, and thermostatic means for permitting operation of said system only upon the ambient temperature of said external environment falling below a predetermined threshold temperature.
  - 18. An energy conversion system as defined in claim 1, said second control means comprising generated current sensing means for providing a current feedback signal the magnitude of current generated by said commutator AC generator means, and means for comparing said demand control signal with said current feedback signal and interconnected with said exciter means to control the degree of excitation of an exciter winding of said commutator AC generator means.
  - 19. An energy conversion system as defined in claim 18, said exciter means comprising bipolar solid state control means constituting a controllable resistance and connected in a series circuit with said exciter winding, for controlling the magnitude of AC current supplied to said exciter winding, said series circuit including an AC voltage source providing an excitation voltage in phase synchronism with said existing AC source, said second control means comprising a differential amplifier adapted for comparing the difference between said current feedback signal and said demand control signal, said differential amplifier having an output controlling said solid state control means to effectively vary the magnitude of said controllable resistance as a function of the difference between said current feedback signal and said demand control signal.
  - 20. An energy conversion system as defined in claim 19 and further comprising filter means for filtering said demand control signal to prevent rapid reduction thereof for rapidly reducing excitation of said exciter winding in response to reduction of the AC power requirements of said load and for permitting slower increase of said demand control signal for slower increase of the excitation of said exciter winding in response to increase of the AC power requirements of said load.

21. An energy conversion system for converting hydrocarbon combustion energy to AC electrical energy for independently supplying demand-controlled supplemental AC electrical power continuously upon demand to an electrical load in electrical phase synchronism with, simultaneously with, and in parallel with an operating, existing source of AC electrical power, said system comprising commutator AC generator means operating at a controllably variable shaft speed unrelated to the frequency of said existing source of AC electrical power, power distribution means interconnecting said system with said existing source of AC electrical power and with said electrical load, a hydrocarbon fueled prime mover for operating said commutator AC generator means, said prime mover being controllable to vary the magnitude of the available mechanical shaft power thereof to produce a controllably variable shaft speed of said commutator AC generator means which shaft speed is unrelated to the frequency of said existing source of AC electrical power, said commutator AC generator means being adapted to generate supplemental AC power for delivery to said electrical load for satisfying AC power requirements of said electrical load, exciter means for exciting said commutator AC generator means proportional to the magnitude of in-phase real power demand of said electrical load regardless of the controllably variable shaft speed of said commutator AC generator means, electrical load current demand sensor means, independent from said operating, existing source of AC power, for providing a demand control signal which is proportional to the magnitude of in-phase real power demand of said electrical load, first control means, including a prime mover output speed feedback loop, interconnected with said prime mover for controlling the production of available mechanical shaft power by said prime mover in proportion to the magnitude of in-phase real power demand of said electrical load, and second control means, including a generated current feedback loop, interconnected with said exciter means for controlling the degree of excitation of said commutator AC generator means to cause the electrical power output thereof to substantially meet and be continually responsive to the magnitude of in-phase real power demand of said electrical load regardless of the mechanical shaft power produced by said prime mover and regardless of the controllably variable shaft speed of said commutator AC generator means, phase sensitive detector means, operatively associated with said power distribution means, for sensing voltage-current phase relationship of AC electrical power provided by said existing source to said electrical load by said power distribution means, and adapted for generating an error signal which is a function of said voltage-current phase relationship, and signal summer means for summing said error signal and said demand control signal, the summed signals being provided to said second control means for nullifying voltage-current phase errors resulting from operation of said system or for preventing flow of AC electrical power from said system to said existing source.

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Current Assignee
Charles A. Berner
Original Assignee
Charles A. Berner
Inventors
Berner, Charles A.
Primary Examiner(s)
Truhe, J. V.
Assistant Examiner(s)
Wade, Shelley

Application Number

US06/015,456
Time in Patent Office

778 Days
Field of Search

290/2, 290/5, 290/7, 290/8, 290/40 B, 323/5, 323/103, 323/104, 323/115-118, 307/44, 307/47, 307/53, 307/57, 307/64, 307/127, 307/131, 307/68
US Class Current

290/7
CPC Class Codes

F02B 2075/025   two

F02B 2075/027   four

F02D 29/06   peculiar to engines driving...

F02G 5/00   Profiting from waste heat o...

F02G 5/02   Profiting from waste heat o...

F02N 11/04   the motors being associated...

H01F 38/30   Constructions

H02J 3/46   Controlling of the sharing ...

H02J 3/48   Controlling the sharing of ...

Y02T 10/12   Improving ICE efficiencies

Y10S 174/15   in a power generation syste...

Supplemental electrical power generating system

First Claim

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Abstract

146 Citations

21 Claims

Specification

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Supplemental electrical power generating system

First Claim

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Accused Products

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Abstract

146 Citations

21 Claims

Specification

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Solutions

Use Cases

Quick Links