CN210806856U - E-type wireless power transmission device - Google Patents

Abstract

The application provides a E type wireless power transmission device, the device includes: the direct-current power supply module is used for supplying energy to the E-type power amplifier high-frequency generation module at the transmitting end; the transmitting terminal starting and controlling circuit unit is used for controlling the transmitting terminal E-type power amplifier high-frequency generating module; the transmitting end E-type power amplifier high-frequency generation module is used for inverting the direct current into alternating current sinusoidal half waves and transmitting the alternating current sinusoidal half waves to the transmitting end SPSS matching network; the transmitting end SPSS matching network is used for converting the alternating current sine half-wave into a high-frequency alternating current sine wave and transmitting the high-frequency alternating current sine wave to the receiving end series resonance network; the receiving end series resonance network is used for receiving the high-frequency alternating-current sine wave and transmitting the high-frequency alternating-current sine wave to the receiving end rectification module; the receiving end rectifying module is used for converting the high-frequency alternating-current sine wave into direct current and outputting the direct current to a load. The problem of load sensitivity among the prior art is solved for the device can still can stably work when the load changes, has improved the performance of device.

Description

E-type wireless power transmission device

Technical Field

The application belongs to the technical field of wireless power transmission, and particularly relates to an E-type wireless power transmission device.

Background

In recent years, the industry of low-power wireless power transmission technology has been developed vigorously, and commercial chain products related to the industry are gradually formed, including well-known low-power consumption handheld electronic devices such as electric toothbrushes, earphones, MP3(Media Player 3), smartwatches, and mobile phones. The charging device of these small power devices generally selects a single-tube power amplifier or the like as a high-frequency inverter circuit, wherein the class-E power amplifier is a single-tube power amplifier circuit topology which is relatively mature in application.

The class-E power amplifier is called E power amplifier for short, and is a high-efficiency power amplifier with power reaching 100% under ideal conditions, namely, the class-E power amplifier can convert all input power of a direct-current power supply into output power when in work. However, in operation, the performance of the transistor and the design of the parameters of the matching network affect the operation efficiency, so that the efficiency cannot reach 100%. Therefore, the class-E power amplifier is designed to compensate for the increase of the transistor loss due to the delay from saturation to cut-off of the parasitic capacitance of the transistor Q in the switching state at high frequency. And, since the transistor operates in the on-off state, the voltage of the choke inductor connected to the drain thereof can be obtained by the following formula:

since the inductor current cannot be transient, the device will generate a large voltage spike to the drain of the transistor at the moment of start-up. When the voltage resistance of the transistor selected by the device is lower than the peak voltage, the transistor is easily damaged.

SUMMERY OF THE UTILITY MODEL

In view of the above, the present application provides a class-E wireless power transmission device, which achieves the purpose of soft start of the device by setting a start and control circuit unit to adjust the operating state of a class-E power amplifier high-frequency generation module at a transmitting end, so that the voltage variation range of the drain-source terminal of a switch tube is reduced, and the technical problem that the transistor is easily damaged when the voltage resistance value of the selected transistor is lower than the start peak voltage is solved; the SPSS matching network structure adopted by the transmitting terminal can realize the voltage constancy of the receiving terminal to a greater extent, well solves the problem of load sensitivity in the prior art, enables the device to work stably when the load changes, improves the performance of the device, and increases the margin of inductor design because the transmitting terminal inductor and the capacitor are in series connection.

The application provides a E type wireless power transmission device, includes: the system comprises a direct-current power supply module, a transmitting end E-type power amplifier high-frequency generation module, a transmitting end starting and control circuit unit, a transmitting end SPSS matching network, a receiving end series resonance network and a receiving end rectification module which are sequentially connected;

the direct-current power supply module is used for supplying energy to the E-type power amplifier high-frequency generation module at the transmitting end;

the transmitting terminal starting and controlling circuit unit is used for controlling the transmitting terminal E-type power amplifier high-frequency generating module;

the transmitting terminal E-type power amplifier high-frequency generation module is used for inverting the direct current into alternating current sinusoidal half waves and transmitting the alternating current sinusoidal half waves to the transmitting terminal SPSS matching network;

the transmitting terminal SPSS matching network is used for converting the alternating current sine half-wave into a high-frequency alternating current sine wave and transmitting the high-frequency alternating current sine wave to the receiving terminal series resonance network;

the receiving end series resonance network is used for receiving a high-frequency alternating-current sine wave and transmitting the high-frequency alternating-current sine wave to the receiving end rectification module;

the receiving end rectifying module is used for converting the high-frequency alternating-current sine wave into direct current and outputting the direct current to a load.

Optionally, the transmitting end class-E power amplifier high-frequency generation module includes an input resonant circuit and a switching tube; the input resonant circuit comprises a choke inductor and an input resonant capacitor; the choke inductor is connected with the switching tube in series; the input resonant capacitor is connected with the switching tube in parallel.

Optionally, the transmission end SPSS matching network includes a first stage series resonant circuit; the first-stage series resonant circuit comprises a first resonant inductor and a first resonant capacitor, and the first resonant inductor is connected with the first resonant capacitor in series.

Optionally, the transmission end SPSS matching network includes a second stage parallel resonant circuit; the second-stage parallel resonant circuit comprises a second resonant inductor and a second resonant capacitor, and the second resonant inductor is connected with the second resonant capacitor in parallel.

Optionally, the transmission end SPSS matching network includes a third stage series resonant circuit; the third-stage series resonant circuit comprises a third resonant inductor and a third resonant capacitor, and the third resonant inductor and the third resonant capacitor are connected in series.

Optionally, the transmission end SPSS matching network includes a fourth stage series resonant circuit; the fourth-stage series resonant circuit comprises a fourth resonant inductor and a fourth resonant capacitor, and the fourth resonant inductor and the fourth resonant capacitor are connected in series.

Optionally, the transmitting terminal starting and controlling circuit unit comprises a voltage sampling unit, and the voltage sampling unit is connected in parallel with a choke inductor in the transmitting terminal class-E power amplifier high-frequency generating module; the voltage sampled value and the set reference value are respectively input to an inverting terminal and a non-inverting terminal of the first-stage comparator; the output of the first-stage comparator and the fixed oscillating triangular wave are respectively input to the inverting terminal and the non-inverting terminal of the second-stage comparator; the output value of the second-stage comparator is input into a duty ratio adjusting unit; the voltage sampling unit, the first-stage comparator, the second-stage comparator and the duty ratio adjusting unit are sequentially connected.

Optionally, the transmitting terminal starting and controlling circuit unit comprises a current sampling unit, and the current sampling unit is connected in series with a choke inductor in the transmitting terminal class-E power amplifier high-frequency generating module; the output end of the current sampling is connected with the current judging unit and then input into the duty ratio adjusting unit, and the current sampling, the current judging unit and the duty ratio adjusting unit are sequentially connected.

Optionally, the input of the duty cycle adjusting unit of the transmitting terminal starting and controlling circuit unit is the output of the second stage comparator and the output of the current determination; the output of the duty ratio control unit is transmitted to a switch tube of a wide-load class-E power amplifier high-frequency generation module; and the duty ratio control unit is connected with a switch tube of the wide-load class-E power amplifier high-frequency generation module in series.

To sum up, the application provides a class-E wireless power transmission device, and the transmitting terminal of the embodiment of the application adopts the SPSS matching network and the transmitting terminal is added with the starting and control circuit unit. In the whole device, the transmitting terminal starting and control circuit unit and the SPSS matching network play a role in starting and stopping. The starting and control circuit unit is arranged to adjust the working state of the E-type power amplifier high-frequency generation module at the transmitting end, so that the purpose of soft starting of the device is achieved, and the E-type power amplifier high-frequency generation module at the transmitting end is controlled to convert direct-current input voltage into high-frequency alternating-current half-wave output, so that the voltage variation range of the drain-source end of the switching tube is reduced, and the technical problem that the transistor is easy to damage when the voltage resistance value of the selected transistor is lower than starting peak voltage is solved; the SPSS matching network at the transmitting end converts the high-frequency alternating-current half-wave into a high-frequency sine wave to be loaded on the transmitting coil, and electric energy is transmitted out through the transmitting coil.

Drawings

Fig. 1 is a circuit diagram of a class E wireless power transmission apparatus according to an embodiment of the present disclosure;

fig. 2 is an equivalent circuit diagram of a class E wireless power transmission device according to an embodiment of the present disclosure;

fig. 3 is a control flowchart of a start control method of a class E wireless power transmission device according to an embodiment of the present application.

Detailed Description

The application provides a class-E wireless power transmission device, and the transmitting terminal of the embodiment of the application adopts an SPSS matching network and is additionally provided with a starting and control circuit unit. The starting and control circuit unit is arranged to adjust the working state of the E-type power amplifier high-frequency generation module at the transmitting end, so that the purpose of soft starting of the device is achieved, the voltage variation range of the drain-source end of the switching tube is reduced, and the technical problem that the transistor is easy to damage when the voltage resistance value of the selected transistor is lower than the starting peak voltage is solved; the SPSS matching network structure adopted by the transmitting terminal can realize the voltage constancy of the receiving terminal to a greater extent, and well solves the problem of load sensitivity in the prior art, so that the device can still stably work when the load changes, and the performance of the device is improved.

The technical solutions of the embodiments of the present application will be described clearly and completely with reference to the accompanying drawings, and it is obvious that the described embodiments are some, but not all, of the embodiments of the present application. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present application without any creative effort belong to the protection scope of the embodiments in the present application.

In the description of the embodiments of the present application, it should be noted that the terms "mounted," "connected," and "connected" are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected unless explicitly stated or limited otherwise; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. Specific meanings of the above terms in the embodiments of the present application can be understood in specific cases by those of ordinary skill in the art.

Referring to fig. 1 to 3, fig. 1 is a circuit diagram of a class E wireless power transmission device according to an embodiment of the present disclosure; fig. 2 is an equivalent circuit diagram of a class E wireless power transmission device according to an embodiment of the present disclosure; fig. 3 is a control flowchart of a start control method of a class E wireless power transmission device according to an embodiment of the present application.

As shown in the circuit diagram of fig. 1, a class E wireless power transmission apparatus of the present application includes:

the system comprises a direct-current power supply module, a transmitting end E-type power amplifier high-frequency generation module, a transmitting end starting and control circuit unit, a transmitting end SPSS matching network, a receiving end series resonance network and a receiving end rectification module which are sequentially connected;

the direct-current power supply module is used for supplying energy to the E-type power amplifier high-frequency generation module at the transmitting end;

the transmitting terminal starting and controlling circuit unit is used for controlling the transmitting terminal E-type power amplifier high-frequency generating module;

the transmitting end E-type power amplifier high-frequency generation module is used for inverting the direct current into alternating current sinusoidal half waves and transmitting the alternating current sinusoidal half waves to the transmitting end SPSS matching network;

the transmitting end SPSS matching network is used for converting the alternating current sine half-wave into a high-frequency alternating current sine wave and transmitting the high-frequency alternating current sine wave to the receiving end series resonance network;

the receiving end series resonance network is used for receiving the high-frequency alternating-current sine wave and transmitting the high-frequency alternating-current sine wave to the receiving end rectification module;

the receiving end rectifying module is used for converting the high-frequency alternating-current sine wave into direct current and outputting the direct current to a load.

It should be noted that, as shown in the circuit diagram of fig. 1, the transmitting end of the magnetic coupling resonant wireless power transmission device with a wide-load class E power amplifier adopts an SPSS matching network, and a starting and control circuit unit is added to the transmitting end. The starting and control circuit unit is arranged to adjust the working state of the E-type power amplifier high-frequency generation module at the transmitting end, so that the purpose of soft starting of the device is achieved; the SPSS matching network at the transmitting end converts the high-frequency alternating-current half-wave into a high-frequency sine wave to be loaded on the transmitting coil, electric energy is transmitted out through the transmitting coil, and the voltage of the receiving end can be constant to a large extent by the SPSS matching network structure adopted at the transmitting end.

Furthermore, the transmitting end class-E power amplifier high-frequency generation module comprises an input resonant circuit and a switch tube; the input resonant circuit comprises a choke inductor and an input resonant capacitor; the choke inductor is connected with the switching tube in series; the input resonant capacitor is connected with the switch tube in parallel.

It should be noted that, as shown in fig. 1, the transmitting end class E power amplifier high frequency generating module includes an input resonant circuit and a switching tube Q; the input resonant circuit includes a choke inductor L_fAnd an input resonance capacitor C_f(ii) a Choke inductance L_fIs connected with the switching tube Q in series; input resonant capacitor C_fAnd the switching tube Q is connected in parallel. The module is used for inputting direct current into powerPressure V_inInverted into high-frequency AC sine half-wave voltage V_DSAnd then input to the transmission side SPSS matching network.

As shown in FIG. 2, the transmitting terminal SPSS matching network is a four-stage LC series-parallel resonant network, and the SPSS matching network converts a high-frequency alternating-current sine half-wave voltage V_DSConverted into a high-frequency alternating sine wave and then input to the transmitting coil.

Further, the transmission terminal SPSS matching network comprises a four-stage LC (L: inductance, C: capacitance) series-parallel resonant network. The first-stage series resonant circuit comprises a first resonant inductor and a first resonant capacitor, and the first resonant inductor is connected with the first resonant capacitor in series; the second-stage parallel resonant circuit comprises a second resonant inductor and a second resonant capacitor, and the second resonant inductor is connected with the second resonant capacitor in parallel; a third stage series resonant circuit; the third-stage series resonant circuit comprises a third resonant inductor and a third resonant capacitor, and the third resonant inductor is connected with the third resonant capacitor in series. A fourth stage series resonant circuit; the fourth-stage series resonant circuit comprises a fourth resonant inductor and a fourth resonant capacitor, and the fourth resonant inductor is connected with the fourth resonant capacitor in series.

It should be noted that the transmission end SPSS matching network circuit includes a resonant inductor L_s、L_p、L_st、 L_tResonant capacitor C_s、C_p、C_st、C_tAnd the mutual inductance M of the transmitting and receiving coils. Wherein, the resonant inductor L_sAnd a resonance capacitor C_sSeries, resonant inductance L_pAnd a resonance capacitor C_pParallel resonant inductor L_stAnd a resonance capacitor C_stSeries, resonant inductance L_tAnd a resonance capacitor C_tAre connected in series. Transmitting terminal SPSS matching network enables high-frequency alternating current sine half-wave voltage V_DSThe high-frequency alternating sine wave is converted into a high-frequency alternating sine wave and is input into the transmitting coil, the receiving end LC series circuit generates resonance at the moment, and the energy of the transmitting end is transmitted to the receiving end in a mode of resonance of the transmitting and receiving circuit. Fig. 2 is a simplified circuit diagram of the transmitting end circuit shown in fig. 1.

The electric energy transmission is carried out through the alternating magnetic field, the reflection impedance of the LCCL resonant network at the receiving end of the amplifying device can be calculated by utilizing the order reduction mode of the resonant network, and then the coupling relation of the energy of the whole device is determined.

The total order of the simplified circuit model of the transmitting end SPSS matching network and the receiving end LC resonant network of the wide-load class-E power amplifier magnetic coupling resonant wireless power transmission device, as shown in FIG. 2, is 8 orders, and in order to reduce the calculation of the related inductance and capacitance parameters of the transmitting end SPSS matching network of the device, the calculation can be performed in a manner of reducing the order of the resonant circuit. The specific calculation process is as follows:

parasitic capacitance or external capacitance C of switch tube_fThe condition is a precondition for realizing ZVS (Zero Voltage Switch) by the switching tube; the receiving end resonance module comprises an LC circuit which is in parallel connection with a full bridge rectifier connected with a rear stage during resonance, and the impedance property of a resonance network of the receiving end cannot be influenced. At this time, the total impedance of the receiving end can be obtained by calculation through a formula, and the total impedance is as follows:

in the above equation, the sum of imaginary parts of impedances at resonance is zero, that is:

the transmitting end resonance module and the receiving end resonance module of the amplifying device form loose coupling through the transmitting coil M, the total impedance of the receiving end can be coupled back to the transmitting end, and the size of the reflected impedance is as follows:

wherein the coupling coefficient M can be calculated by the following formula:

where k is a coupling factor between the two coils, and the magnitude of k is a positive number smaller than 1, depending on the shape, positional relationship, medium in the coil, and the like of the two coils. Preferably, k is 0.1 to 0.7.

Based on the above analysis, the total equivalent impedance of the simplified device of the circuit in the device is:

at high frequencies, in order to reduce switching losses of the switching tube, the current crossover regions through which the drain and source turn-off of the switching tube flow are small, i.e., ZVS (Zero Voltage Switch) needs to be implemented. When the direct current and fundamental wave components of the drain voltage of the switching tube are conducted in the switching tube of the first half period, the switching frequency and the requirement for realizing ZVS input resonance network L_f、C_fThe frequency relationship of (A) is:

in order to achieve the best transmission effect over a certain load range, the resonant frequency of its input resonant network can be changed accordingly. To achieve this effect, the input resonant network can be at the minimum load by changing the parallel capacitance Cf of the switching tube within a certain range, and the relationship is as follows:

generally, α is a number between 0 and 0.8, and the actual value can be specifically set according to the use situation, and in the embodiment of the present application, the value of α is preferably 0.7.

Thus, the input resonant network capacitance C_fCan be obtained by the following formula:

the capacitance C can be calculated by combining the formulas (6), (7) and (8)_fThe value of (a).

It should be noted that, as can be seen from fig. 1, the first-stage series resonant circuit of the transmitting-end resonant circuit is formed by connecting a first inductor and a first capacitor in series, the first-stage series resonant circuit and the second-stage parallel resonant circuit respectively determine a maximum quality factor Q value and a minimum quality factor Q value of a resonant network in the amplifying device, and the device can normally operate in a wide range by adjusting a value of Q.

As can be seen from fig. 1, the second-stage parallel resonant circuit of the transmitting-side resonant circuit is formed by connecting a second inductor and a second capacitor in parallel, and the most suitable quality factor of the first-stage series resonant circuit and the second-stage parallel resonant circuit of the amplifying device at the corresponding minimum load or the most suitable quality factor at the maximum load is:

the selection of the Qopt determines the load bearing capacity of the device, and when the device works normally, the preferred Qopt is selected to be 4.5 or 5, so that a wide load range can be realized.

For the first series resonant circuit, at rated load, the capacitance C_sThe following relationship is provided between the optimum Q value:

the capacitance C can be calculated by combining the equations (9) and (10)_s。

For the second parallel resonant circuit, at nominal load, the minimum load is related to the resonant circuit as follows:

the inductance can be obtained by the following formula:

the capacitance C is obtained by calculation from the equations (11) and (12)_p。

It should be noted that, the third-stage series resonant circuit is formed by connecting a third inductor and a third capacitor in series, and in order to make the SPSS matching network at the transmitting end have a wider load range, the frequency should be slightly less than the switching tube operating frequency fsw when calculating the inductance and capacitance parameters of the fourth-stage series resonant circuit.

In addition, in the calculation of the inductance and capacitance parameters of the fourth-stage series resonant circuit, it is also necessary to consider that the transmission-side SPSS matching network has a wide load range, so that the resonant frequency fsw2 of the fourth-stage series resonant circuit needs to be slightly shifted from the frequency fsw1 of the third-stage series resonant circuit.

When the coil of the inductor is wound, the inductance of the inductor is influenced by factors such as the shape of the coil, the number of winding turns, the distance between every two turns of the coil, the material for winding the coil, the addition of a magnetic material and the like, and the capacitance can be determined firstly, and then the inductance value can be determined. And after the inductance of the coil after the actual winding is measured, correspondingly adjusting the capacitance value.

Furthermore, the transmitting end starting and controlling circuit unit comprises a voltage sampling unit, and the voltage sampling unit is connected with a choke inductor in the transmitting end class-E power amplifier high-frequency generating module in parallel; the value after voltage sampling and a set reference value are respectively input to an inverting terminal and a non-inverting terminal of the first-stage comparator; the output of the first-stage comparator and the fixed oscillation triangular wave are respectively input to the inverting terminal and the non-inverting terminal of the second-stage comparator; the output value of the second-stage comparator is input into a duty ratio adjusting unit; the voltage sampling unit, the first-stage comparator, the second-stage comparator and the duty ratio adjusting unit are sequentially connected.

It should be noted that, as shown in fig. 1, the receiving-end circuit includes a receiving resonant inductor L_RReceiving resonant capacitor C_R(ii) a Receiving end rectifying circuit D₁、D₂、D₃、D₄，D₁、D₂Are connected in series to form a group D₃、D₄Are connected in series to form another group. The receiving end LC series resonance circuit inputs the received high-frequency sine wave into a receiving end rectifying circuit to be converted into direct current. In order to ensure high transmission efficiency of the device, when the circuit parameters of the resonant network of the receiving end are calculated, the resonant frequency is consistent with the resonant frequency of the transmitting end, and the series resonance of the inductor and the capacitor is greatly helpful for the parameter design of the receiving end. In order to obtain the best power transmission effect, the inductance values of the transmitting coil and the receiving coil are kept consistent. According to the relation between the inductance and the capacitance during resonance, the corresponding inductance and capacitance parameters can be obtained.

Furthermore, the transmitting end starting and controlling circuit unit comprises a current sampling unit, and the current sampling unit is connected in series with a choke inductor in the transmitting end class E power amplifier high-frequency generation module; the output end of the current sampling is connected with the current judging unit and then input into the duty ratio regulating unit, and the current sampling, the current judging unit and the duty ratio regulating unit are sequentially connected.

It should be noted that, as shown in fig. 1, the sampling feedback module includes a two-stage comparator. Voltage of inductance V_LfThe sampling circuit is scaled down and then sent to the inverting input end of the first-stage comparator, and the inverting input end of the first-stage comparator is connected with the normal drain working voltage V of the switching tube_{MOS_D}And comparing, wherein the output value of the comparator is sent to the inverting input end of the second-stage comparator, a triangular wave related to driving is generated for comparison to generate a driving signal, the current flowing through the choking inductor is collected for auxiliary judgment, and a driving pulse with a variable duty ratio is generated so as to control the working state of the switching tube.

Furthermore, the input of the duty ratio adjusting unit of the transmitting terminal starting and controlling circuit unit is the output of the second-stage comparator and the output of the current judgment; the output of the duty ratio control unit is transmitted to a switch tube of a wide-load class-E power amplifier high-frequency generation module; the duty ratio control unit is connected with a switch tube of the wide-load class-E power amplifier high-frequency generation module in series.

It should be noted that, because the maximum input of the micro control unit connected to the sampling feedback module is 3.3V, when the scaled sampling voltage is greater than 3.3V, the micro control unit will be damaged, so the scaled voltage is generally collected by using a resistance voltage division method. After sampling, the analog quantity is converted into digital quantity and stored in Resultx (x is a positive integer from 0 to 15), if the result register is n bits, the maximum sampling value is 2n, and the actual sampling value can be obtained according to the corresponding relation. The detailed sample comparison process is shown in fig. 3.

It should be noted that the start control of the start control module is divided into three steps: 1) detecting the terminal voltage and the current of the choke inductor in an initial state to judge whether the device is in an initial working state; 2) when the device is in an initial working state, the control module is started to generate a driving signal with a duty ratio lower than the designed duty ratio D to drive the switching tube to work; 3) and when the end current and the end voltage of the choke inductor are stable, the digital control module adjusts the current duty ratio D to an actual design value. Suppose the output voltage of the choke inductor is V_LfThe drain voltage of the switching tube is V during normal operation_{MOS_D}. Real-time sampling of terminal voltage V of choke inductor by voltage current detection circuit_LfAnd the voltage is transmitted to the digital control module and the set drain voltage V of the switching tube in normal operation_{MOS_D}And performing comparison operation.

It should be noted that five operating conditions may occur when the amplifying device is in operation. The first condition is as follows: when the device works normally, the device operates according to a set duty ratio D; case two: when the device starts up, the device operation duty ratio D is changed by detecting corresponding choke inductance parameters, and when the choke inductance parameters are detected within a reasonable range, the current duty ratio is set; case three: when the power amplifier does not work, the device judges that the power amplifier does not work temporarily 2; case four: when the power amplifier does not supply power, the device judges that the power amplifier does not work temporarily 1; case five: when the voltage and current parameters of the choke inductor are detected to be totally abnormal, the device is in failure.

The application provides a class-E power amplification device, including high frequency generation module based on class-E power amplifier, the first order series LC resonance network that is used for primary impedance transformation, the second order parallel LC resonance network that is used for primary impedance transformation, the third order series LC resonance network that is used for primary impedance transformation, the series LC resonance network that is used for vice side impedance transformation, receiving terminal resonant circuit, full-bridge rectifier circuit module, load. The direct current power supply can be chopped into square waves with certain frequency through the E-type power amplifier high-frequency generation module. The square wave is converted into a high-frequency sine wave through the primary side three-stage LC series-parallel resonant network, and finally the energy is transmitted out through the transmitting coil. The receiving coil is connected with the receiving end resonance network and generates coupling resonance with the primary side, and the received energy is converted into direct-current voltage for the load to use after passing through the full-bridge rectifier circuit module. The primary side three-stage LC series-parallel resonant network enables the class-E power amplifier to have a wide load range; the circuit of the starting control module of the device comprises a resistance voltage division sampling circuit connected to the rear end of a choke inductor, an input current sampling circuit connected to the front end of the choke inductor, and a sampled numerical value is sent to a connected control unit for calculation after passing through a sampling conditioning circuit, so that the working state of a switching tube is controlled. According to the magnetic coupling resonance wireless power transmission device, the appropriate resonance networks are respectively added on the primary side and the secondary side of the resonance wireless power transmission system, the E-type power amplifier can still be in the best working state under the condition that the load changes, meanwhile, the voltage and current overshoot of the switch tube is reduced through the starting control of the system, the system obtains better transmission efficiency, and the performance of the magnetic coupling resonance wireless power transmission device based on the improved E-type power amplifier is improved.

The above embodiments are only used for illustrating the technical solutions of the present application, and not for limiting the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions in the embodiments of the present application.

Claims (9)

1. A class E wireless power transfer apparatus, comprising:

the system comprises a direct-current power supply module, a transmitting end E-type power amplifier high-frequency generation module, a transmitting end starting and control circuit unit, a transmitting end SPSS matching network, a receiving end series resonance network and a receiving end rectification module which are sequentially connected;

the direct-current power supply module is used for supplying energy to the E-type power amplifier high-frequency generation module at the transmitting end;

the transmitting terminal starting and controlling circuit unit is used for controlling the transmitting terminal E-type power amplifier high-frequency generating module;

the transmitting terminal E-type power amplifier high-frequency generation module is used for inverting the direct current into alternating current sinusoidal half waves and transmitting the alternating current sinusoidal half waves to the transmitting terminal SPSS matching network;

the transmitting terminal SPSS matching network is used for converting the alternating current sine half-wave into a high-frequency alternating current sine wave and transmitting the high-frequency alternating current sine wave to the receiving terminal series resonance network;

the receiving end series resonance network is used for receiving a high-frequency alternating-current sine wave and transmitting the high-frequency alternating-current sine wave to the receiving end rectification module;

the receiving end rectifying module is used for converting the high-frequency alternating-current sine wave into direct current and outputting the direct current to a load.

2. The class-E wireless power transmission device according to claim 1, wherein the transmitting-end class-E power amplifier high-frequency generation module comprises an input resonant circuit and a switch tube; the input resonant circuit comprises a choke inductor and an input resonant capacitor; the choke inductor is connected with the switching tube in series; the input resonant capacitor is connected with the switching tube in parallel.

3. The class-E wireless power transfer apparatus of claim 1, wherein the transmit side SPSS matching network comprises a first stage series resonant circuit; the first-stage series resonant circuit comprises a first resonant inductor and a first resonant capacitor, and the first resonant inductor is connected with the first resonant capacitor in series.

4. The class-E wireless power transfer apparatus of claim 1, wherein the transmit side SPSS matching network comprises a second stage parallel resonant circuit; the second-stage parallel resonant circuit comprises a second resonant inductor and a second resonant capacitor, and the second resonant inductor is connected with the second resonant capacitor in parallel.

5. The class-E wireless power transfer apparatus of claim 1, wherein the transmit side SPSS matching network comprises a third stage series resonant circuit; the third-stage series resonant circuit comprises a third resonant inductor and a third resonant capacitor, and the third resonant inductor and the third resonant capacitor are connected in series.

6. The class-E wireless power transfer apparatus of claim 1, wherein the transmit side SPSS matching network comprises a fourth order series resonant circuit; the fourth-stage series resonant circuit comprises a fourth resonant inductor and a fourth resonant capacitor, and the fourth resonant inductor and the fourth resonant capacitor are connected in series.

7. The class-E wireless power transmission device according to claim 1, wherein the transmitting terminal starting and control circuit unit comprises a voltage sampling unit, and the voltage sampling unit is connected in parallel with a choke inductor in the transmitting terminal class-E power amplifier high-frequency generation module; the voltage sampled value and the set reference value are respectively input to an inverting terminal and a non-inverting terminal of the first-stage comparator; the output of the first-stage comparator and the fixed oscillating triangular wave are respectively input to the inverting terminal and the non-inverting terminal of the second-stage comparator; the output value of the second-stage comparator is input into a duty ratio adjusting unit; the voltage sampling unit, the first-stage comparator, the second-stage comparator and the duty ratio adjusting unit are sequentially connected.

8. The class-E wireless power transmission device according to claim 1 or 7, wherein the transmitting terminal starting and control circuit unit comprises a current sampling unit, and the current sampling unit is connected in series with a choke inductor in a transmitting terminal class-E power amplifier high-frequency generation module; the output end of the current sampling is connected with the current judging unit and then input into the duty ratio adjusting unit, and the current sampling, the current judging unit and the duty ratio adjusting unit are sequentially connected.

9. The class-E wireless power transmission device according to claim 8, wherein the input of the duty cycle adjusting unit of the transmitting terminal starting and controlling circuit unit is the output of the second stage comparator and the output of the current determination; the output of the duty ratio control unit is transmitted to a switch tube of a wide-load class-E power amplifier high-frequency generation module; and the duty ratio control unit is connected with a switch tube of the wide-load class-E power amplifier high-frequency generation module in series.

Images