TH61437B - Multi-phase induction power supply system - Google Patents

Abstract

DC60 (11/01/59) Multi-Phase Induction Power Supplies wirelessly transmit power in multi-phase. The primary circuit will give Multiple parallel resonant power in a different phase relationship The secondary circuit will receive power and combine. Reunited The amount of power in each phase is reduced as compared to the power transfer. The same quantity using a single phase induction power supply. Edit Conclusion 11/01/2016 Multi-phase induction power supplies wirelessly transmit multi-phase power. The primary circuit will give Multiple parallel resonant power in a different phase relationship The secondary circuit will receive power and combine. My strength together again The amount of power in each phase is reduced as compared to the power transfer. Same quantity using a single phase induction power supply -------------------------------------------------- ---------- Multi-phase induction power supplies wirelessly transmit power in multiple phases. Pathomphumi circuit gives Energy to the tank circuit in a phase relationship The secondary circuit receives power and consolidates. With a new shift The amount of power in and phase is reduced as compared to the quantity energy transfer. The same, using a single-phase induction power supply.

Claims (7)

Disclaimer (all) which will not appear on the advertisement page: EDIT 11/01/2016 1. Multi-Phase Induction Power Supply System That includes DC power source, grounding, microprocessor A number of parallel resonant circuits Where each parallel resonance circuit includes a Connect the primary inductance and the capacitor. A number of signal generators Where each of the aforementioned signal generators is Connect electrically to the microprocessor. Where the microprocessor sends a signal Give each of these a number of these signal generators to generate oscillations in a relationship. Phases from each other of a number of such signal generators Where the microprocessor will transmit The signal is given to each of the aforementioned signal generators to vary their timing. Swing the instrument on the basis of feedback from a remote device. A number of drivers Where each one of the aforementioned drivers is electrically connected to the Generates at least one such number of signals A number of switching circuits Where each such number of switching circuits is Electrical connection with at least one of the aforementioned drivers. And where a number of switching circuits As mentioned, each circuit is either electrically connected, such a DC source or ground. With one such parallel resonant circuit to generate alternating current Where each alternating current The body will be in that heterogeneous relationship. Multiphase inductive secondary circuits connected to such remote devices by connectors. A certain amount of secondary inductance Where each aforementioned number of secondary inductive connectors will Connect inductively to at least one such primary inductive connector in the circuit. Each such number of parallel resonance circuits Where a number of secondary inductive connectors Each of these generates a current in a different phase relationship. Where the remote device Such a feedback is provided through the said induction connection. A number of aforementioned secondary inductance connectors are electrically connected phase integrated circuits. For including the aforementioned differential current 2. Multi-phase induction power supply system according to claim 1, where the inductive connector Some of these primates are placed in overlapping triangles so that The voltages from adjacent primary inductive connectors offset each other. 3. Multi-phase inductive power supply system in accordance with claim 1, where the inductive connectors. A number of such secondary are arranged in an overlapping triangular relationship. 4. Multi-phase inductive power supply system according to claim 1, where the inductive coupling A number of such primary ones are loosely arranged in a linear manner 5. Multi-phase inductive power supply system according to claim 1, where the inductive connectors A number of such primary ones are arranged in a loosely overlapped non-overlapping triangle. 6. Multi-phase induction power supply system according to claim 1, where the phase of the signal source Each signal generator is offset 120 degrees from the phase of the signal generator. 7. Multi-phase induction power supply system according to claim 1, where the phase of the signal Each signal generator is offset 30 degrees from another generator signal, such as At least one signal. 8. Multi-phase induction power supply system according to claim 1, where such feedback This will be based on the power supply requirements of the aforementioned remote devices. 9. Multi-phase inductive power supply system according to claim 1, which is included further. Loads that are electrically connected to such phase ICs 1 0. Multi-phase inductive power supply that receives feedback from a remote device. Such multi-phase induction power supply includes A number of parallel resonant circuits Where a number of such parallel resonant circuits, but Each circuit will include a primary inductive connector for connecting the inductance to the inductive connector. Secondary of the remote device A multiphase induction primary circuit will power a number of parallel resonant circuits. Each circuit at a different phase in such a way that a number of such long-resonant circuits are supplied. Side-phase energy Such a multiphase induction primary circuit will vary the timing of the Provides such power on the basis of feedback from remote devices in parallel resonant circuits. One such number, at least one circuit. Where the feedback signal is received from the inductor connector. The secondary of the remote device is passed through such inductive coupling of the parallel resonant circuit. At least one such circuit 1. 1. Multiphase inductive power supply according to claim 10, where the parallel resonant circuit One such number is arranged in an overlapping triangular relationship to provide energy from The adjacent parallel resonant circuit refutes 1 2. Multi-phase inductive power supply according to claim 10, where the resonant circuit is parallel. A number of these are loosely arranged in a linear manner 1 3. Multiphase inductive power supply according to claim 10, where the parallel resonant circuit resonates. One such number is arranged in a loosely overlapped non-overlapping triangle. 1 4. Multi-phase inductive power supply according to claim 10, where each phase is induced. Overlapping at least 120 degrees from each other 1 5. Multi-phase inductive power supply according to claim 10, where each phase is Overlap at least 30 degrees from each other ------------------------------------------ -------------------------------------------------- ----------------------------- 1. Multi-phase induction power supply system Included DC power source, ground, microprocessor A number of tank circuits Where each tank circuit includes a body to connect the primary lead And capacitors One number of oscillators Where each one of these oscillators is Electrical connection with micro Such processor Where the microprocessor sends a signal Give each one of these oscillators a oscillating signal in a relationship. Phase from each other of a number of these oscillators. A number of drivers Where each one of the aforementioned drivers is electrically connected to At least one such oscillator. A number of switching circuits Which a number of such switching circuits, each circuit will be connected Electrically with at least one such number of drivers And which a number of such switching circuits Each circuit chooses to connect either the said DC source or to ground electrically to the The tank circuit is a circuit to generate alternating current. Where each alternating current will be in nature Relationships are different phases, said. A multiphase inductive secondary circuit with a number of secondary inductive connectors, where each such number of secondary inductive connectors is welded by inductance to the connector. At least one such primary inductor in each of the aforementioned tank circuits, each of which each of the aforementioned secondary inductors generates current in a relationship. Such different phase A phase circuit that is electrically connected to a number of such secondary inductive connectors. 2. The multi-phase inductive power supply system, according to claim 1, where the inductive connector A number of such primary ones are arranged in an overlapping triangular relationship. 3. The multi-phase inductive power supply system, according to claim 1, where the inductive connectors are connected to each other so that the voltages from adjacent primary inductive connectors offset each other. A number of such secondary are arranged in an overlapping triangular relationship. 4. Multi-phase inductive power supply system according to claim 1, where the inductive connector A number of such primary ones are arranged in a linear and non-adjacent manner. 5. Multi-phase induction power supply system according to claim 1, where the inductive connectors A number of such primary ones are arranged in a non-overlapping and non-adjacent triangle. 6. Multi-phase inductive power supply system according to claim 1, where the signal phases are not overlapped. Each oscillator is offset 120 degrees from the phase of the other oscillator signal. 7. Multi-phase induction power supply system according to claim 1, where the phase of the signal Each oscillator is offset 30 degrees from at least one other oscillator signal. 8. Multi-phase inductive power supply. That includes A number of tank circuits A multiphase induction primary circuit supplies power to a number of such tank circuits. Circuits with different frequencies in such a way that a certain number of tank circuits receive power in phase overlapping 9. Multi-phase inductive power supply according to claim 8, where a number of tank circuits They are arranged in an overlapping triangular relationship to provide energy. From adjacent tank circuits offset 1 0. Multi-phase inductive power supply according to claim 8, where a number of tank circuits Such are arranged in a linear and non-adjacent manner. 1. Multiphase power supply according to claim 8, where a number of tank circuits They will be arranged as a non-overlapping and non-adjacent triangle. 2. Multiphase power supply according to claim 8, where each phase is Overlap at least 120 degrees from each other 1 3. Multiphase inductive power supply according to claim 8, where each phase is Overlap at least 30 degrees from each other 1 4.Multi-phase inductive secondary circuit for receiving power from a multi-phase induction power source. The aforementioned multiphase inductive secondary circuit will include A number of secondary windings for power from the said multi-phase inductive power supply, a phase integrated circuit that is electrically connected to a number of such secondary windings for integration. The power received from such a multi-phase induction power supply is recombined. Loads that are electrically connected to said phase 1 circuits. 5. Multiphase induced secondary circuit according to claim 14, where a number of secondary windings They are arranged in an overlapping triangular relationship to provide power. From adjacent tank circuits offset 1 6. Multiphase induced secondary circuits according to claim 14, where a number of secondary windings Such are arranged in a linear and non-adjacent manner. 7. Multiphase induced secondary circuit according to claim 14, where a number of secondary windings They are arranged in a non-overlapping and non-adjacent triangle.