| CPC H02J 50/12 (2016.02) [H01Q 1/2291 (2013.01); H01Q 1/248 (2013.01); H02J 50/20 (2016.02); H02J 50/402 (2020.01); H02J 50/90 (2016.02); H02J 2207/20 (2020.01)] | 5 Claims |
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1. A wireless charging transmission apparatus by using three-dimensional (3D) polyhedral magnetic resonance based on multi-antenna switching, comprising a magnetic resonance wireless energy transmitting module, a plurality of magnetic resonance transmitting antennas, a plurality of receiving antennas, and a magnetic resonance wireless energy receiving module, wherein the magnetic resonance wireless energy transmitting module, the plurality of magnetic resonance transmitting antennas, the plurality of receiving antennas, and the magnetic resonance wireless energy receiving module are connected in sequence; wherein
the magnetic resonance wireless energy transmitting module is configured to convert direct current (DC) power into radio frequency (RF) energy, transmit the RF energy to the plurality of magnetic resonance transmitting antennas, and control an operation mode of the wireless charging transmission apparatus;
the plurality of magnetic resonance transmitting antennas are configured to convert the RF energy into a spatially distributed reactive field;
the plurality of receiving antennas are configured to generate a magnetic resonance coupling together with the plurality of magnetic resonance transmitting antennas and convert the spatially distributed reactive field into the RF energy;
the magnetic resonance wireless energy receiving module is configured to convert the RF energy into DC power and charge or power a load;
the magnetic resonance wireless energy transmitting module comprises a power adapter, a voltage regulator circuit, a transmitting Bluetooth detection circuit, a frequency modulation circuit, a drive circuit, an RF power amplifier circuit, a plurality of LC matching networks, a plurality of main circuit switches, a plurality of transmitting resonant capacitors, a plurality of relay coupling capacitors, and a plurality of capacitor switching switches;
the power adapter, the voltage regulator circuit and the transmitting Bluetooth detection circuit are communicatively connected in sequence; the voltage regulator circuit is communicatively connected to the frequency modulation circuit and the RF power amplifier circuit, respectively; the frequency modulation circuit is communicatively connected to the RF power amplifier circuit through the drive circuit; the RF power amplifier circuit, the plurality of LC matching networks, and the plurality of main circuit switches are communicatively connected in sequence; the plurality of main circuit switches are communicatively connected to the plurality of capacitor switching switches through the plurality of transmitting resonant capacitors and the plurality of relay coupling capacitors; the transmitting Bluetooth detection circuit is further communicatively connected to the plurality of main circuit switches and the plurality of capacitor switching switches, respectively; and the plurality of capacitor switching switches are communicatively connected to the plurality of magnetic resonance transmitting antennas;
the power adapter is configured to convert 220 V alternating current (AC) power to DC power and power the magnetic resonance wireless energy transmitting module;
the voltage regulator circuit is configured to regulate an input voltage;
the transmitting Bluetooth detection circuit is configured to acquire positions of the plurality of receiving antennas and control the operation mode of the wireless charging transmission apparatus, wherein the operation mode comprises resonance matching and relay coupling matching;
the frequency modulation circuit is configured to modulate a transmitting operation frequency and convert the DC power to an RF signal;
the drive circuit is configured to drive the RF power amplifier circuit;
the RF power amplifier circuit is configured to amplify power of wireless energy;
the plurality of LC matching networks and series-parallel resonant capacitor banks are in one-to-one correspondence to the plurality of magnetic resonance transmitting antennas to form series-parallel transmitting LC resonant circuits, wherein the series-parallel transmitting LC resonant circuits are configured to determine a resonant frequency of the wireless charging transmission apparatus;
when the plurality of LC matching networks and the series-parallel resonant capacitor banks are in one-to-one correspondence to the plurality of magnetic resonance transmitting antennas to form a plurality of resonant transmitting antennas, some of the plurality of magnetic resonance transmitting antennas operate at the resonant frequency, and the rest magnetic resonance transmitting antennas are connected to the plurality of relay coupling capacitors to form a plurality of relay coupling antennas, wherein the plurality of relay coupling antennas operate at a relay coupling frequency;
the plurality of transmitting resonant capacitors are in one-to-one correspondence to the plurality of magnetic resonance transmitting antennas to form series LC resonant circuits, and the resonant frequency of the wireless charging transmission apparatus is controlled by adjusting parameters of the plurality of transmitting resonant capacitors;
the plurality of relay coupling capacitors are in one-to-one correspondence to the plurality of magnetic resonance transmitting antennas to form series LC relay coupling resonant circuits, and the relay coupling frequency of the wireless charging transmission apparatus is controlled by adjusting parameters of the plurality of relay coupling capacitors;
the plurality of main circuit switches are configured to switch a main RF circuit of the wireless charging transmission apparatus between on and off;
the plurality of capacitor switching switches are configured to switch between the plurality of transmitting resonant capacitors and the plurality of relay coupling capacitors;
the plurality of magnetic resonance transmitting antennas are wound on an outer wall of a 3D polyhedron, and comprise a plurality of groups of transmitting coils and a plurality of energy feed inlets; the plurality of energy feed inlets are respectively fastened on each group of transmitting coils of the plurality of groups of transmitting coils; and each group of transmitting coils is wound on the outer wall of the 3D polyhedron in a first winding manner, a second winding manner, or a third winding manner; and
in the second winding manner, each group of transmitting coils comprises a first transmitting coil and a second transmitting coil, and the first transmitting coil and the second transmitting coil are arranged in parallel on the outer wall of the 3D polyhedron within a preset length, cross at a preset angle after reaching the preset length, continue to be arranged in parallel on the outer wall of the 3D polyhedron after crossing, and cross at the preset angle again after reaching a next preset length; and each of the plurality of energy feed inlets is fastened at a fold line, wherein the first transmitting coil and the second transmitting coil cross at the preset angle at the fold line.
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