KR20220154957A - Wireless power transfer apparatus and design method thereof - Google Patents

Abstract

A wireless power transceiver having maximum efficiency is disclosed. The wireless power transceiver comprises: a PFC converter performing power factor improvement; an IPT converter transmitting power from a transmission side to a reception side by electromagnetic induction method; and a BM converter controlling an output according to the remaining capacity of a battery. The IPT converter comprises: a transmitter part; and a receiver part. The IPT converter comprises a compensation circuit designed based on an optimal output voltage derived based on a loss analysis of the transmitter part and receiver part. The BM converter is designed based on a variation range of an optimum output voltage according to a variation range of the coupling coefficient of the IPT converter and a battery charging voltage range.

Description

Wireless power transceiver and design method thereof {WIRELESS POWER TRANSFER APPARATUS AND DESIGN METHOD THEREOF}

The present invention relates to a wireless power transceiver and a design method thereof.

Recently, as the demand for convenience of consumers increases, wireless charging technology with advantages of convenience compared to wired charging is attracting attention in the fields of portable electronic devices and electric vehicle chargers.

The wireless charging method may be classified into an electromagnetic induction method, a magnetic resonance method, and an electromagnetic wave method. Among them, the electromagnetic induction method has advantages over the wired charging method in terms of electrical spark, leakage current, and stability.

As shown in FIG. 1, the wireless charging system using the electromagnetic induction method includes a PFC converter for power factor correction, an IPT converter for electromagnetic induction method (Inductive Power Transfer, IPT) for transmitting power from a transmitting side to a receiving side, and a battery. It consists of a battery management (BM) converter that controls the output according to the remaining capacity (State of Charge, SOC).

Unlike general transformers, in the case of a wireless charging system, the VA rating of the system can be greatly increased because the coupling coefficient (k) representing the degree of magnetic coupling between the transmitting and receiving coils is a very small Loosely Coupled Transformer (LCT).

To overcome this, compensation circuits having various output characteristics may be applied to the IPT converter.

The compensation circuit has constant current (CC) or constant voltage (CV) characteristics according to load fluctuations.

Considering the characteristics of the battery, it is generally advantageous to apply a compensation circuit having CV characteristics.

Among compensation circuits with CV characteristics, the LCC-S compensation method has the advantage that there is no Zero Phase Angle (ZPA) frequency fluctuation depending on the load and that the current flowing through the transmitting coil can be supplied constantly regardless of the load and coupling coefficient fluctuation.

Publication No. 10-2017-0143166 (published on December 29, 2017)

An object to be solved by the present invention is to design and provide a wireless power transmission/reception device having maximum efficiency.

An object to be solved by the present invention is to provide a method for designing an IPT converter and a BM converter having optimized efficiency by analyzing the loss of a transmission/reception system.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

An apparatus for transmitting and receiving wireless power according to an aspect of the present invention for solving the above problems includes a PFC converter for performing power factor correction; IPT converter for transmitting power from the transmission side to the reception side by electromagnetic induction; and a BM converter that controls an output according to the remaining capacity of the battery, wherein the IPT converter includes a transmitter and a receiver, wherein the IPT converter generates an optimal output voltage derived based on loss analysis of the transmitter and receiver. and a compensation circuit designed based on the design, and the BM converter is characterized in that it is designed based on a variation range of an optimum output voltage according to a variation range of the coupling coefficient of the IPT converter and a battery charging voltage range.

In an embodiment, the transmitting unit of the IPT converter includes a full bridge inverter, a first compensating circuit, and a transmitting pad, and the receiving unit of the IPT converter includes a receiving pad, a second compensating circuit, and a rectifier.

In an embodiment, the first compensation circuit and the second compensation circuit are characterized in that they are determined based on a DC-L_ink voltage, an output voltage, a resonant frequency, and an LCT parameter between a transmission pad and a reception pad.

In an embodiment, the current flowing through the transmitting unit of the IPT converter is proportional to the output voltage of the IPT converter, and the current flowing through the receiving unit of the IPT converter is inversely proportional to the output voltage of the IPT converter.

In an embodiment, the optimal output voltage is an output voltage set to have maximum efficiency according to a load by comparing and analyzing a loss of the transmitter and a loss of the receiver according to the output voltage of the IPT converter.

In an embodiment, the first compensation circuit included in the transmission unit includes an inductor, a first capacitor, and a second capacitor, and the loss of the transmission unit is the loss of the inductor, the loss of the first capacitor, and the second capacitor. It is characterized in that it includes the loss of the capacitor and the loss of the transmission pad.

In an embodiment, the loss of the transmitter is characterized in that it increases in proportion to the magnitude of the output voltage of the IPT converter.

In an embodiment, the second compensation circuit included in the receiving unit may include a third capacitor, and the loss of the receiving unit may include a loss of the third capacitor and a loss of the receiving pad.

In an embodiment, the loss of the receiver is reduced in proportion to the magnitude of the output voltage of the IPT converter.

In an embodiment, the loss of the receiving unit is characterized in that it increases according to an increase in the load applied to the IPT converter.

In an embodiment, the BM converter is characterized in that a boost converter, which is a step-up converter, is used when the charging voltage range of the battery is greater than the output voltage of the IPT converter in all sections.

In an embodiment, the BM converter is characterized in that it is a buck-boost converter that controls an output voltage to enable step-up and step-down.

Other specific details of the invention are included in the detailed description and drawings.

According to the present invention, by deriving the optimal output voltage of the IPT converter to which the LCC-S resonance method is applied in the wireless charging system, and designing the IPT converter and the BM converter accordingly, optimal design of wireless charging systems such as unmanned transporters and electric vehicles has the effect that is possible.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

1 is a conceptual diagram illustrating a wireless power transmission and reception device of the present invention.
2 is a circuit diagram showing the IPT converter of the present invention.
3 is a flowchart illustrating a method of designing a wireless power transmission and reception device of the present invention.
4 is a graph showing LCC-S compensation components and current according to the output voltage of the IPT converter.
5 is a graph showing the loss of the IPT converter according to the output voltage of the IPT converter.
6 is a graph showing the loss and efficiency of the IPT converter according to the output voltage for each case.
7 is a graph showing the efficiency of the IPT converter according to the output voltage for each case at the minimum coupling coefficient.
8 is a diagram showing experimental waveforms for each case at the minimum coupling coefficient.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, only these embodiments are intended to complete the disclosure of the present invention, and are common in the art to which the present invention belongs. It is provided to fully inform the person skilled in the art of the scope of the invention, and the invention is only defined by the scope of the claims.

Terminology used herein is for describing the embodiments and is not intended to limit the present invention. In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase. As used herein, "comprises" and/or "comprising" does not exclude the presence or addition of one or more other elements other than the recited elements. Like reference numerals throughout the specification refer to like elements, and “and/or” includes each and every combination of one or more of the recited elements. Although "first", "second", etc. are used to describe various components, these components are not limited by these terms, of course. These terms are only used to distinguish one component from another. Accordingly, it goes without saying that the first element mentioned below may also be the second element within the technical spirit of the present invention.

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used with meanings commonly understood by those skilled in the art to which the present invention belongs. In addition, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless explicitly specifically defined.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram illustrating a wireless power transmission and reception device of the present invention.

A wireless power transmission/reception device (or wireless charging system) according to an embodiment of the present invention may use an electromagnetic induction method.

As shown in FIG. 1, a wireless power transmission/reception device using an electromagnetic induction method transmits power from a transmission side to a reception side using a PFC converter that performs power factor correction and an electromagnetic induction method (Inductive Power Transfer (IPT)). It consists of a battery management (BM) converter that controls the output according to the remaining capacity (State of Charge, SOC) of the battery.

The IPT converter may include a transmitter and a receiver.

The IPT converter may include a compensation circuit designed based on an optimal output voltage derived based on loss analysis of the transmission unit and the reception unit.

In the IPT converter to which the LCC-S compensation circuit is applied, the compensation circuit can be designed according to the input DC-L_ink voltage, output voltage, and transmission/reception PAD parameters.

Therefore, it is possible to have output voltage characteristics of various IPT converters by designing the compensation circuit differently at a constant DC-L_ink voltage.

In general, the output voltage of the IPT converter can be designed around the range of the input voltage of the BM converter and the coupling coefficient of the transmit/receive pad.

Since the output voltage of the IPT converter to which the LCC-S compensation method is applied is induced by the transmission side current, it can be expected that the loss of the transmission/reception PAD (pad) and compensation circuit varies according to the output voltage setting.

Accordingly, the present invention analyzes the loss of the transmission and reception systems (transmission and reception of the IPT converter) according to the output voltage of the IPT converter to determine the output voltage having the maximum efficiency at light load, medium load, and heavy load in a system having the same rated power. each can be derived.

In addition, the BM converter can be selected in consideration of the derived output voltage, the variation range of the coupling coefficient, and the charging voltage of the battery.

Specifically, the BM converter included in the apparatus for transmitting and receiving wireless power of the present invention may be designed based on the optimal output voltage variation range and battery charging voltage range according to the coupling coefficient variation range of the IPT converter.

In the present invention, whether the design method described in this specification is valid was verified by manufacturing a 3.3kW class H/W.

As a result of the experiment, the efficiency of the IPT converter and BM converter designed to have maximum efficiency at light load is up to 90.1% at 820W, the system designed to have maximum efficiency at medium load is up to 91.7% at 1435W, and the system designed to have maximum efficiency at heavy load was confirmed to have a maximum efficiency of 93.0% at 2800W.

Hereinafter, a method of designing a wireless power transmission/reception device to have maximum efficiency and a wireless power transmission/reception device according thereto will be described in more detail with reference to the accompanying drawings.

2 is a circuit diagram showing an IPT converter of the present invention, and FIG. 3 is a flowchart showing a method of designing a wireless power transmission and reception device of the present invention.

The present invention may include an LCC-S compensation type IPT converter.

Referring to FIG. 2 , the transmission unit of the IPT converter may include a full bridge inverter, a first compensation circuit, and a transmission pad, and the reception unit of the IPT converter may include a reception pad, a second compensation circuit, and a rectifier.

Specifically, the IPT converter to which the LCC-S compensation circuit is applied may include a transmission unit composed of a full bridge inverter, a first compensation circuit, and a transmission pad (PAD), and a reception section composed of a reception pad (PAD), a second compensation circuit, and a rectifier. have.

In the case of the compensation circuit, it can be determined by the DC-L_ink voltage, the output voltage, the resonance frequency, and the LCT parameter of the transmit/receive pad (PAD).

That is, the first compensation circuit and the second compensation circuit may be determined (or designed) based on DC-L_ink voltage, output voltage, resonant frequency, and LCT parameters between the transmission pad and the reception pad.

The size of each current of the IPT converter can also be determined as shown in Equations 1 to 4 by the input/output voltage and the transmit/receive PAD parameters.

Regardless of the size of U_ab, except for I_in, which is proportional to the output power (P_out), all currents in the transmitter (system) are proportional to the output voltage (U_ab) of the IPT converter.

Conversely, the current I_s of the receiver is inversely proportional to the output voltage of the IPT converter.

Therefore, it is possible to derive the optimal output voltage of the IPT converter having the maximum efficiency according to the load by analyzing and comparing the loss of the transmitter and the receiver according to the output voltage of the IPT converter.

That is, the currents (I_C_p, I_p) flowing through the transmitter of the IPT converter may be proportional to the output voltage of the IPT converter, and the current flowing through the receiver of the IPT converter may be inversely proportional to the output voltage of the IPT converter.

In addition, the optimal output voltage may be an output voltage set to have maximum efficiency according to a load by comparing and analyzing a loss of the transmitting unit and a loss of the receiving unit according to the output voltage of the IPT converter.

In the present invention, in order to distinguish the output voltage of the IPT converter and the output voltage of the BM converter, the output voltage of the IPT converter is described as an output voltage, and the output voltage of the BM converter is referred to as a battery charging voltage.

Referring to FIG. 3, the method of designing a wireless power transmission/reception device of the present invention includes specifying electrical specifications of an IPT converter (S310), designing the shape, dimensions, and parameters of an LCT (S320), based on loss analysis and designing an IPT converter using a compensation circuit (S330) and designing a BM converter based on the range of variation of the optimal output voltage according to the range of variation of the coupling coefficient of the IPT converter and the range of battery charging voltage (S340). can

4 is a graph showing LCC-S compensation components and current according to the output voltage of the IPT converter.

Transmitter loss analysis of IPT converter is as follows.

The transmission part of the IPT converter is composed of a full bridge inverter, a transmission-side compensation circuit (first compensation circuit), and a transmission PAD.

The loss of a full bridge inverter consists of conduction loss, switching loss, parasitic capacitor loss, and diode loss.

That is, the loss of the transmitter may include a loss of the inductor, a loss of the first capacitor, a loss of the second capacitor, and a loss of the transmission pad.

Conduction loss and switching loss proportional to I_in account for the largest portion of inverter loss. In the case of I_in, as shown in FIG. 3, it is proportional to the output power regardless of the output voltage when operating in ZPA. Therefore, it can be seen that the loss of the inverter is independent of the output voltage.

The transmission-side compensation circuit (the first compensation circuit included in the transmission unit) is composed of an inductor (L_in), a first capacitor (C_p), and a second capacitor (C_f).

The loss of an inductor is divided into copper loss and iron loss. When designing an inductor through the same litz wire and core, the loss of the inductor is determined in proportion to I_in and the size of the inductance. Depending on the output voltage, I_in is constant and L_in is inversely proportional to the output voltage, so the inductance value is determined, so the loss of the inductor is inversely proportional to the output voltage.

The loss of a capacitor can be calculated through the dissipation factor (DF), which is the ratio of reactance (Xc) component and equivalent series resistance.

In the case of the first capacitor C_p, since it increases in proportion to the output voltage, it can be expected that the value of the equivalent series resistance decreases.

On the other hand, I_cp increases in proportion to the output voltage as shown in equation (2). Therefore, it can be seen that the loss of C_p increases according to the output voltage, but the increase is not large due to the inversely proportional equivalent series resistance.

In the case of the second capacitor C_f, since it decreases in inverse proportion to the output voltage, the value of the equivalent series resistance increases. Also, since Ip increases in proportion to the output voltage as shown in Equation (3), the loss of C_f increases according to the output voltage, and the increase is larger than the loss of C_p.

The loss of PAD (transmit pad) on the transmission side is divided into copper loss and iron loss.

In the case of a wireless charging system operating at a high frequency, copper loss of Litz wire used to minimize copper loss due to skin effect and proximity effect can be divided into loss due to coil resistance and additional loss due to skin effect and proximity effect. However, when Litz wire is used, the amount of loss added due to the skin effect is very small up to a frequency band of 100 kHz, so only the loss due to the resistance of the coil and the loss due to the proximity effect are dealt with in the present invention.

Therefore, in the case of copper loss, since it increases in proportion to the size of the transmission coil current, it can be seen that it is proportional to the output voltage.

In the case of iron loss, since the transmitting and receiving PADs are magnetically coupled, it is necessary to simultaneously analyze the iron loss of the transmitter and receiver.

The iron loss of each PAD can be derived through the Steinmetz Equation. In the case of kcore, α, and β, these are experimentally obtained values. Data is usually provided by the manufacturer. Since this paper used PC95, the iron loss coefficients are 0.074, 1.43 and 2.85, respectively. Unlike general transformers, in the case of a wireless charging system with a lot of leakage flux, FEM simulation can be used to calculate the core loss accurately and the size of the magnetic flux density and the loss of the core can be known.

However, the magnitude of magnetic flux on the transmit/receive side can be derived through the self-inductance, mutual inductance, number of turns, and current on the transmit/receive side.

The magnetic flux of the transmission side can be divided into leakage flux of the transmission side and mutual magnetic flux coupled to the reception side as shown in Equation 6.

The magnetic flux of the receiving side can also be divided into the leakage magnetic flux of the receiving side and the mutual magnetic flux coupled to the transmitting side as shown in Equation 7.

In the case of each leakage flux, it can be derived as in Equation 8 using the leakage inductance derived using the transformer model, the number of turns, and the current size. Mutual magnetic flux can also be derived as shown in Equation 9 through the number of turns and magnetizing current using the magnetizing inductance derived through the transformer model.

Since the mutual magnetic flux is also proportional to the magnitude of the magnetizing current and has the same phase, the magnetic flux on the transmitting side and the magnetic flux on the receiving side can be derived through the vector sum of the total magnetic fluxes of the transmitting side and the receiving side.

In the case of the transmission-side magnetic flux, since the transmission-side leakage flux and mutual flux increase according to the output voltage, it can be seen that the iron loss of the transmission-side PAD is proportional to the output voltage.

In addition, according to the load change, the magnitude of the leakage flux that occupies a large part of the transmission side magnetic flux is constant and the mutual flux increases. Therefore, it can be seen that the increase in the iron loss of the transmission side PAD is not large according to the load change.

In the case of the receiving-side magnetic flux, it can be seen that the leakage flux, which occupies a large portion of the receiving-side magnetic flux, is inversely proportional to the output voltage, and the mutual flux increases proportionally.

Therefore, it can be seen that the iron loss of the receiving side PAD is inversely proportional to the output voltage. In addition, it can be seen that the iron loss of the PAD on the receiving side increases rapidly with the increase in the load, since the leakage flux on the receiving side rapidly changes according to the load change.

That is, the loss of the transmitter may increase in proportion to the magnitude of the output voltage of the IPT converter.

Hereinafter, an analysis of receiver loss of an IPT converter will be described.

The receiving part of the IPT converter is composed of a receiving pad (receiving coil PAD), a second compensation circuit, and a rectifier.

The second compensation circuit included in the receiver may include a third capacitor C_s.

The loss of the receiving unit may include a loss of the third capacitor and a loss of the receiving pad.

It can be seen that the third capacitor C_s has a constant size regardless of the output voltage, and I_s is inversely proportional to the output voltage as shown in Equation 4.

Therefore, it can be seen that the loss of the third capacitor (C_s) is inversely proportional to the output voltage.

The loss of the diode rectifier circuit can be divided into conduction loss and reverse recovery loss.

However, since the Schottky diode is used in the present invention, the reverse recovery loss is very small, so only the conduction loss is considered as shown in Equation 10. It can be seen that the loss of the rectifier is also inversely proportional to the output voltage due to I_s, which is inversely proportional to the output voltage.

5 is a graph showing the loss of the IPT converter according to the output voltage of the IPT converter.

As shown in FIG. 5 , in the case of the transmitter, the loss of the second capacitor C_f and the transmission PAD accounts for the largest part of the loss of the transmitter and can be most sensitively changed according to the output voltage setting.

On the other hand, in the case of the receiver, the loss of all elements is sensitively changed according to the setting of the output voltage.

Loss of the receiver may decrease in proportion to the magnitude of the output voltage of the IPT converter.

Also, the loss of the receiver may increase as the load applied to the IPT converter increases.

Since the total loss of the transmitter and the receiver has an inversely proportional relationship according to the setting of the output voltage, the optimum output voltage may be set differently according to the output power.

In the present invention, based on this analysis, it is possible to select and design the optimal output voltage of the IPT converter according to the main operating range.

For example, in the present invention, a compensation circuit can be designed by analyzing the loss of a 3.3kW class IPT converter based on the above analysis and selecting an optimal output voltage. In addition, the BM converter can be designed in consideration of the optimal output voltage variation range and battery charging voltage range according to the coupling coefficient variation range.

The electrical specifications of the IPT converter are the same as in Table 1, the switch of the IPT converter uses a C3M0030090K Mosfet element, and the diode element of the rectifier uses an IDW20G120C5B Schottky diode.

In the present invention, the battery charging method is designed to be charged through the BM converter at a fixed resonant frequency. Table 2 shows the electrical parameter and coupling coefficient variation range of the transmitting and receiving PAD.

Since the optimum output voltage of the IPT converter varies depending on the output power, it is necessary to select a different output voltage according to the main operating point. Therefore, as shown in Table 3, Case 1 under the light load condition mainly operated at 820W with a rated output of 3.3kW, Case 2 under the medium load condition mainly operated at 1435W, and Case 3 under the heavy load condition mainly operated at 2800W were classified as Cases. Thus, the loss according to the output voltage is analyzed at each main operating point, and the efficiency of the IPT converter can be predicted as shown in FIG. 6. 6 is a graph showing the loss and efficiency of the IPT converter according to the output voltage for each case.

Through loss analysis, the optimal output voltage of Case 1, which is mainly operated at 820W, is 130V, the optimal output voltage of Case 2, which is mainly operated at 1435W, is 170V, and the optimal output voltage of Case 3, which is mainly operated at 2800W, is 220V. .

A BM converter can be selected in consideration of the derived output voltage and the charging voltage of the battery.

In Case 1, since the charging voltage range of the battery is larger than the output voltage of the IPT converter in all sections, a boost converter, a boost converter, can be used. That is, the BM converter may use a boost converter, which is a step-up converter, when the charging voltage range of the battery is greater than the output voltage of the IPT converter in all sections.

In cases 2 and 3, the output voltage must be controlled so that step-up and step-down are possible using a buck-boost converter. That is, the BM converter may be a buck-boost converter that controls an output voltage to enable step-up and step-down.

7 is a graph showing the efficiency of the IPT converter according to the output voltage for each case at the minimum coupling coefficient, and FIG. 8 is a diagram showing the experimental waveform for each case at the minimum coupling coefficient.

The verification through experiments is as follows.

With the resonant frequency and DC-link voltage fixed based on the minimum coupling coefficient, a 3.3kW rated IPT converter was fabricated for each case, and a BM converter was fabricated considering the output voltage and battery charging voltage. When designing the compensating inductor, the same Litz wire and PC95 core were used in all cases, and when designing the capacitor, 2.2nF ceramic capacitors were used in combination in series and parallel.

7 shows the efficiency of the IPT converter and the BM converter and the output voltage of the IPT converter in the entire load range for each case. At the minimum coupling coefficient point, it can be seen that case 1 achieves an efficiency of up to 90.1% at 820W, case 2 achieves an efficiency of up to 91.7% at 1435W, and case 3 achieves an efficiency of up to 93.0% at 2800W.

8 shows the output voltage and output current of the inverter and the output voltage and output current of the IPT converter at the point of maximum efficiency for each case. In Case 1, the output voltage is 130V at 820W, in Case 2, the output voltage is 170V at 1435W, and in Case 3, the output voltage is 220V at 2800W, and it can be seen that ZVS (Zero Voltage Switching) is satisfied in all cases. .

Accordingly, in the present invention, in order to derive the optimal output voltage of the IPT converter to which the LCC-S resonance method is applied in the wireless charging system, it is possible to compare and analyze the loss of the transmitter and receiver.

Through the proposed loss analysis method, it is possible to derive the optimal output voltage according to the main operating range and design the IPT converter and BM converter accordingly.

As a result of the experiment, it can be seen that the loss of the transmitter of the IPT converter increases and the loss of the receiver decreases in proportion to the magnitude of the output voltage.

In addition, it can be seen that the loss of the transmitter hardly fluctuates as the load increases, while the loss of the receiver greatly increases.

Therefore, through the optimal output voltage design method proposed in the present invention, it is possible to optimally design wireless charging systems such as unmanned vehicles and electric vehicles.

Steps of a method or algorithm described in connection with an embodiment of the present invention may be implemented directly in hardware, implemented in a software module executed by hardware, or implemented by a combination thereof. A software module may include random access memory (RAM), read only memory (ROM), erasable programmable ROM (EPROM), electrically erasable programmable ROM (EEPROM), flash memory, hard disk, removable disk, CD-ROM, or It may reside in any form of computer readable recording medium well known in the art to which the present invention pertains.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. you will be able to understand Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

Claims (12)

a PFC converter that performs power factor correction;
IPT converter for transmitting power from the transmission side to the reception side by electromagnetic induction; and
Including a BM converter that controls the output according to the remaining capacity of the battery,
The IPT converter includes a transmitter and a receiver,
The IPT converter includes a compensation circuit designed based on the optimal output voltage derived based on the loss analysis of the transmitter and receiver,
The wireless power transmission and reception device, characterized in that the BM converter is designed based on a variation range of an optimal output voltage according to a variation range of the coupling coefficient of the IPT converter and a battery charging voltage range. According to claim 1,
The transmission unit of the IPT converter includes a full bridge inverter, a first compensation circuit and a transmission pad,
The receiving unit of the IPT converter includes a receiving pad, a second compensation circuit, and a rectifier. According to claim 2,
The first compensation circuit and the second compensation circuit,
Wireless power transmission and reception device, characterized in that determined based on the DC-link voltage, output voltage, resonance frequency, and LCT parameters between the transmission pad and the reception pad. According to claim 2,
The current flowing through the transmitter of the IPT converter is proportional to the output voltage of the IPT converter,
Wireless power transmission and reception device, characterized in that the current flowing in the receiver of the IPT converter is inversely proportional to the output voltage of the IPT converter. According to claim 4,
The optimal output voltage is,
Wireless power transmission and reception device, characterized in that the output voltage is set to have a maximum efficiency according to the load by comparing and analyzing the loss of the transmitter and the loss of the receiver according to the output voltage of the IPT converter. According to claim 5,
The first compensation circuit included in the transmission unit,
Including an inductor, a first capacitor and a second capacitor,
The loss of the transmitter is,
Wireless power transmission and reception device characterized in that it comprises a loss of the inductor, a loss of the first capacitor, a loss of the second capacitor, and a loss of the transmission pad. According to claim 6,
The wireless power transmission and reception device, characterized in that the loss of the transmitter increases in proportion to the magnitude of the output voltage of the IPT converter. According to claim 5,
The second compensation circuit included in the receiver includes a third capacitor,
The loss of the receiver is,
Wireless power transmission and reception device characterized in that it comprises a loss of the third capacitor and a loss of the receiving pad. According to claim 8,
The wireless power transmission and reception device, characterized in that the loss of the receiver decreases in proportion to the magnitude of the output voltage of the IPT converter. According to claim 8,
The wireless power transmission and reception device, characterized in that the loss of the receiver increases according to the increase in the load applied to the IPT converter. According to claim 1,
The BM converter,
When the charging voltage range of the battery is greater than the output voltage of the IPT converter in all sections, a boost converter, which is a step-up converter, is used. According to claim 1,
The BM converter,
A wireless power transmission and reception device, characterized in that it is a buck-boost converter that controls the output voltage to enable step-up and step-down.

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