CN112366777A - Constant-current constant-voltage induction type wireless charging system based on secondary variable structure - Google Patents

Abstract

A constant current constant voltage induction type wireless charging system based on a transformer structure comprises a receiving part: receiving coil L_sAnd a compensation capacitor C_sAnd a compensation capacitor C_fAnd a compensation inductance L_fThe rectifier filters R are sequentially connected in series; constant voltage compensation capacitor C_SVAnd a first switch S₁One end of the series capacitor is connected with a compensation capacitor C_sAnd a compensation capacitor C_fIs connected with a common point of the constant voltage compensation capacitor C_SVAnd a first switch S₁The other end of the series connection is connected with a receiving coil L_sIs connected with the common point of the rectifier filter R; constant current compensation capacitor C_SCAnd a second change-over switch S₂One end of the series capacitor is connected with a compensation capacitor C_sAnd a receiving coil L_sIs connected with a constant current compensation capacitor C_SCAnd a second change-over switch S₂The other end of the series connection and the compensation inductor L_fAnd a compensation capacitor C_fAre connected. By controlling the first switch S₁And a first switch S₂The system realizes constant voltage and constant current output.

Description

Constant-current constant-voltage induction type wireless charging system based on secondary variable structure

Technical Field

The invention relates to an induction type wireless charging system.

Background

The inductive wireless power transmission technology is a novel power supply mode for transmitting electric energy to a load in a non-contact mode through an electromagnetic induction principle. The contactless charging technology of the electric automobile is gradually favored by enterprises and consumers due to the characteristics of convenience, rapidness and safety, can enhance the competitiveness of the electric automobile relative to the traditional fossil energy automobile, promotes the development of the electric automobile industry, and has wide application and development prospects.

In order to prolong the service life and the charging times of the vehicle-mounted battery and improve the safety of a charging system, the charging process of the battery is mainly divided into two charging modes of constant current and constant voltage: in the initial charging stage, the constant current charging mode is adopted, and the voltage of the battery rises; when the voltage of the battery reaches the charging set voltage, the system enters a constant voltage charging mode, the charging current is gradually reduced to the charging cut-off current, and the charging of the battery is finished. Therefore, the inductive wireless power transmission system applied to battery charging needs to realize two working modes of constant current and constant voltage output.

The existing induction type wireless charging system mainly comprises: the power frequency alternating current is rectified to obtain direct current voltage, then the direct current is converted into high frequency alternating current by the high frequency inverter and injected into the transmitting coil to generate a high frequency alternating magnetic field; the receiving coil obtains induced electromotive force through electromagnetic induction, obtains direct current after high-frequency rectification, and provides electric energy for a load. Since the equivalent impedance of the battery is constantly changed during the charging process, the charging system needs to control the output voltage and current in real time. To solve this problem, the following methods are generally adopted: firstly, closed-loop feedback control is adopted in a circuit system, for example, after communication equipment is adopted to feed back a direct current voltage and a current signal rectified and output by a receiving side to a primary side control system, phase shift control or PWM control is adopted for a high-frequency inverter so as to regulate the output voltage and the output current of the system; or a high-frequency controllable rectifier is adopted on the receiving side, and the output voltage and current of the system are regulated by adopting phase-shift control or PWM control; the DC-DC converter can also be cascaded after the rectification of the receiving side; the drawback is that the control cost and complexity are increased and the system stability is reduced. And secondly, frequency conversion control is adopted, constant-current constant-voltage output is realized by adjusting the working frequency of the system, but in a system with a frequency bifurcation phenomenon, the method is easy to cause unstable system operation.

The system topology structure or parameters are changed through the change-over switch, and the system constant voltage and constant current output is realized by a relatively simple and effective method. However, for a rectifier circuit, the existing method generally equates the rectified input impedance to pure resistance, and the method simplifies the analysis process, neglects the pure resistance of the rectifier bridge, and is not suitable for a system with a large-range load change.

In the application occasions of high-power wireless charging such as an electric bus, the gap between a transmitting coil and a receiving coil is large, the mutual inductance between the transmitting coil and the receiving coil is small, and when an LCC topological structure is adopted on a receiving side, the compensation inductance is generally small, so that the input current of a rectifier is seriously distorted, and an intermittent state appears, so that the output voltage change rate of the system is large in a constant voltage charging mode.

Li Tree, in the literature "Analysis of the input impedance of the receiver and design of LCC compensation network of the DWPT system [ J ]. IET Power Electronics,2019,12 (10): 2678-.

Jili in the document' design of an electric vehicle wireless charging system with automatic charging mode switching at secondary side [ J ] power system automation, 2017(23): 137-. However, the ground side adopts the LCC compensation structure, so that the harmonic content of the inverter output current is large, the power capacity of the inverter is increased, and the efficiency is low. The receiving side adopts an LCC compensation structure, and the input current of the rectifier can be in an intermittent state, so that the output voltage of the system is changed.

Jili proposes a function of realizing constant-voltage and constant-current charging automatic switching by changing capacitance of a compensation capacitor in a document 'research and design of a wireless power transmission system with a secondary side automatically switching charging mode based on an LCL resonance compensation network [ J ]. report of electrotechnical science, 2018,33(S1): 38-44', but does not consider the influence of the interruption of input current of a rectifier on output voltage and current of the system.

In the topology structure disclosed in chinese patent 201610318334.2, "an inductive wireless power transmission system capable of outputting both constant current and constant voltage", a primary side and a receiving side simultaneously adopt a series compensation structure, and the system has poor parameter offset resistance and poor robustness. Chinese patent 201610814192.9, "constant current and constant voltage induction type wireless charging system based on variable primary parameters", discloses an induction type wireless charging system topology structure capable of realizing constant current and constant voltage charging, but the primary side of the structure adopts series compensation, the receiving side adopts LCC compensation, the receiving side compensation inductance must be designed according to the output current and the receiving side induction voltage, and the condition of interruption of the rectifier input current is not considered. Chinese patent 201710217941.4, "an inductive wireless charging system with secondary variable parameters and variable structure", describes that the system structure and parameters change simultaneously during the constant voltage and constant current charging process of the topology structure. In the topological structure disclosed in chinese patent 201610814224.5, "a constant current and constant voltage induction type wireless charging system", the receiving side is of an LCC structure, which easily causes serious distortion of input current of a rectifier and an intermittent state, resulting in a large rate of change of output voltage of the system when outputting a constant voltage, and thus the structure is not suitable for a system with a load changing in a large range.

Xiaohui Qu describes a variable-structure Constant-Current and Constant-Voltage Charging topology which realizes system Constant-Current and Constant-Voltage Output by changing the topology in the documents Qu X, Han H, Wong S C, et al. When constant current is output, the primary side and the secondary side of the system are both in series compensation structures, and the robustness is poor; when the constant voltage is output, the primary side is of an LCC structure, the design of the compensation inductor of the primary side cannot be freely designed, and the higher harmonics of the output current of the inverter cannot be effectively inhibited.

C Auvigne, in the literature "a dual-topology ICPT applied to an electric vehicle battery charger [ C ]. in proc.int. conf.electric.mach.2012 pp.2287-2292", describes an inductive wireless power transfer system by varying the constant voltage and constant current output of the secondary structure. When constant current is output, the primary side and the secondary side of the system are both in series compensation structures, and the robustness is poor; when the constant voltage is output, the receiving side is of an LCC structure, the intermittent working state of the input current of the rectifier is easy to occur, so that the constant output voltage cannot be ensured when the constant voltage is output, and the structure is not suitable for a system with a load changing in a large range.

Disclosure of Invention

The invention aims to enable an induction type wireless charging system to realize constant current and constant voltage output, simultaneously keep the input current of a rectifier filter continuous in a wide load range and ensure the output voltage of the system to be constant in the wide load range in a constant voltage charging mode, and provides a constant current and constant voltage induction type wireless charging system based on a variable secondary structure.

The invention is suitable for the situation of charging batteries, in particular to a wireless charging system with high power and large transmission distance, such as an electric bus and a rail transit wireless charging system.

The technical scheme adopted by the invention is as follows:

a constant-current constant-voltage induction type wireless charging system based on a transformer structure is composed of a transmitting part and a receiving part. The transmitting part comprises a direct current power supply, a high-frequency inverter, a compensating capacitor and a transmitting coil which are connected in sequence; the receiving part comprises a receiving coil, a constant current and constant voltage switching circuit, a rectifier filter and a battery load which are connected in sequence. It is characterized in that a constant voltage and constant current switching circuit is connected in series between the receiving coil and the rectifier.

The constant-current constant-voltage switching circuit comprises the following components:

receiving coil L_sAnd a compensation capacitor C_sAnd a compensation capacitor C_fAnd a compensation inductance L_fAnd the rectifier filters R are connected in series in sequence; constant voltage compensation capacitor C_SVAnd a first switch S₁One end of the series capacitor is connected with a compensation capacitor C_sAnd a compensation capacitor C_fIs connected with a common point of the constant voltage compensation capacitor C_SVAnd a first switch S₁The other end of the series connection is connected with a receiving coil L_sIs connected with the common point of the rectifier filter R; constant current compensation capacitor C_SCAnd a second change-over switch S₂One end of the series capacitor is connected with a compensation capacitor C_sAnd a receiving coil L_sIs connected with a constant current compensation capacitor C_SCAnd a second change-over switch S₂The other end of the series connection and a compensation inductor L_fAnd a compensation capacitor C_fAre connected. First change-over switch S₁And a first switch S₂Is connected with the controller K.

The first change-over switch S₁Closed, the second change-over switch S₂When the wireless charging system is disconnected, the wireless charging system realizes constant voltage output; the first change-over switch S₁Off, the second change-over switch S₂And when the wireless charging system is closed, the constant current output is realized.

The compensation inductance L_fThe compensation inductor L plays a main role in ensuring the input current of the rectifier to be continuous, and in order to ensure that the input current of the rectifier filter is continuous in a wide load range when the wireless charging system is charged at a constant voltage, the compensation inductor L_fInductance value of

Determined by formula (1):

in the formula (1), pi is the circumferential ratio, omega is the angular frequency of system operation, V_BVoltage value set for constant voltage charging of battery, I_BThe current value is set when the battery is charged with constant current.

The transmitting coil L_PAnd a receiving coil L_sThe mutual inductance therebetween is determined by equation (2):

in the formula (2), the reaction mixture is,

is the voltage value of the DC power supply E, pi is the circumferential rate, omega is the angular frequency of system operation, I_BThe voltage value is set when the battery is charged with constant current.

The compensation capacitor C_fCapacitance value of

Determined by equation (3):

in the formula (3), pi is the circumferential ratio, omega is the angular frequency of system operation, I_BThe current value set when the battery is in constant current charging,

is the value of the voltage of the direct current power supply E,

for compensating inductance L_fSensitivity value of V_BThe voltage value is set when the battery is charged at constant voltage.

The compensation capacitor C_sCapacitance value of

Determined by equation (4):

in the formula (4), pi is the circumferential ratio, omega is the angular frequency of system operation, I_BThe current value set when the battery is in constant current charging,

is the value of the voltage of the direct current power supply E,

is a receiving coil L_sInductance value of, V_BThe voltage value is set when the battery is charged at constant voltage.

The constant voltage compensation capacitor C_SVCapacitance value of

Determined by equation (5):

in the formula (5), pi is the circumferential ratio, omega is the angular frequency of system operation, I_BCurrent value, V, set for constant-current charging of the battery_BThe voltage value is set when the battery is charged at constant voltage.

The constant current compensation capacitor C_SCCapacitance value of

Determined by equation (6):

in the formula (6), pi is the circumferential ratio, omega is the angular frequency of the system,

is the voltage value of the DC power supply E, I_BThe current value set when the battery is in constant current charging,

for compensating inductance L_fThe sensitivity value of (a) to (b),

is a receiving coil L_sSensitivity value of V_BThe voltage value is set when the battery is charged at constant voltage.

The controller K controls the first switch S₁Off, second change-over switch S₂When the wireless charging system is closed, the wireless charging system works in a constant current mode, and constant current is output to a load on a receiving side, namely, the set constant charging current I is provided for the battery_B(ii) a The method is suitable for the constant current charging stage at the initial stage of battery charging.

The controller K controls the first switch S₁Closed, second change-over switch S₂When the charging system is disconnected, namely the charging system works in a constant voltage mode, constant voltage is output to the load at the receiving side, namely the set constant charging voltage V is provided for the battery_B(ii) a The method is suitable for the constant voltage charging stage in the later charging stage of the battery.

The theoretical analysis and circuit principle of the charging system for outputting constant current and constant voltage are as follows:

let the angular frequency of system operation be ω and satisfy the following relation:

in the formula (7), the reaction mixture is,

transmitting coil L_PThe inductance value of (a) is set,

compensating the capacitance C for the primary side_PIs not limited toThe value of the one or more of,

for compensating inductance L_fThe inductance value of (a) is set,

to compensate for capacitance C_fThe capacity value of (a) is,

compensating the capacitor C for constant voltage_SVThe capacity value of (a) is,

is a receiving coil L_sThe inductance value of (a) is set,

in order to compensate the capacitance value of the capacitor at the receiving side,

compensating the capacitor C for constant current_SCThe capacity value of (c).

The receiving side is an LCCC compensation structure in a constant voltage mode and compensates an inductor L_fThe method mainly plays a role in ensuring the input current of the rectifier filter to be continuous, and the condition that the input current of the rectifier filter is continuous is as follows:

in the formula (8), R_eIs the alternating current equivalent load of the battery load, omega is the system working angular frequency,

for compensating inductance L_fJ is an imaginary symbol.

In the constant-voltage charging stage, the output current of the system is gradually reduced, and the equivalent load resistance R is_eGradually increasing, setting the input current of the rectifier filter to be continuous when the charging current is reduced to 10% of the constant current charging current in the constant voltage charging stageThe expression of the system equivalent load resistance is as follows:

in the formula (9), pi is a circumferential ratio, V_BSetting the charging voltage for constant-voltage charging, I_BThe current value is set during constant current charging.

When the charging current is reduced to 10% of the constant-current charging current in the constant-voltage charging stage, the input current of the rectifier filter is still continuous, so that the output voltage of the charging system is kept unchanged in the constant-voltage charging mode stage of the battery, and the condition of compensating inductance according to the receiving side of the formula (8) and the formula (9) needs to be met:

in the formula (10), pi is the circumferential ratio, omega is the angular frequency of system operation, V_BSetting the charging voltage for constant-voltage charging, I_BThe current value is set during constant current charging.

In the charging system of the invention, in a constant current working mode, a transmitting part and a receiving part are both in series compensation structure, and according to kirchhoff voltage and current law, the relationship of each electric quantity of the system can be deduced as follows:

in the formula (11), the reaction mixture is,

is the fundamental component of the output voltage of the high-frequency inverter, omega is the angular frequency of system operation,

transmitting coil L_PThe inductance value of (a) is set,

is a transmitting coil L_PThe current of (a) is measured,

compensating the capacitance C for the primary side_PM is the transmitting coil L_PAnd a receiving coil L_sThe mutual inductance between the two parts is changed,

in order to receive the current of the coil,

is a receiving coil L_sThe inductance value of (a) is set,

for compensating inductance L_fThe inductance value of (a) is set,

in order to compensate the capacitance value of the capacitor at the receiving side,

to compensate for capacitance C_fThe capacity value of (a) is,

compensating the capacitor C for constant current_SCJ is an imaginary symbol.

From equations (7) and (11), the receive coil current is:

in the formula (12), the reaction mixture is,

is the voltage value of the DC power supply E, pi is the circumferential rate, omega is the angular frequency of the system operation, M is the transmitting coil L_PAnd a receiving coil L_sThe mutual inductance value between them.

Receiving coil current and DC transmission according to circuit basic knowledgeDischarging and charging current I_BThe relationship of (1) is:

in the formula (13), the reaction mixture is,

for receiving the coil current, I_BThe current value is set during constant current charging.

According to the formulas (12) and (13), the transmitting coil L is obtained in the constant current charging process_PAnd a receiving coil L_sThe mutual inductance M therebetween is determined by equation (14):

in the formula (14), the compound represented by the formula (I),

is the voltage value of the DC power supply E, pi is the circumferential rate, omega is the angular frequency of system operation, I_BThe current value is set during constant current charging.

In the charging system of the invention, under a constant voltage working mode, a transmitting part is in series compensation, a receiving part is in a compensation structure of LCC, and according to kirchhoff voltage and current laws, the relationship of each electric quantity of the system can be deduced as follows:

in the formula (15), the reaction mixture is,

is the fundamental component of the output voltage of the inverter H, j is an imaginary number sign, omega is the angular frequency of system operation,

is a transmitting coil L_pThe inductance value of (a) is set,

compensating the capacitance C for the primary side_pThe capacity value of (a) is,

is a transmitting coil L_PM is the transmitting coil L_PAnd a receiving coil L_sThe mutual inductance between the two parts is changed,

is a receiving coil L_sThe current of (a) is measured,

is a receiving coil L_sThe inductance value of (a) is set,

compensating the capacitance C for the receiving side_sCapacity value of (A), R_eThe battery is an alternating-current equivalent load,

is the fundamental wave component of the alternating voltage at the input end of the rectifier,

is the fundamental content of the rectifier current,

compensating the capacitor C for constant voltage_SVThe capacity value of (a) is,

compensating the capacitance C for constant voltage flow_SVThe current of (2).

The receiving coil current expression is as follows from equations (7) and (15):

in the formula (16), pi is the circumferential ratio and omega is the angular frequency of system operationJ is an imaginary symbol, V_BA charging voltage is set for constant-voltage charging,

for compensating inductance L_fThe inductance value of (a) is set,

to compensate for capacitance C_fThe capacity value of (a) is,

to compensate for capacitance C_SVThe capacity value of (c).

Receiving the current of the coil

The relation with the ground DC power supply E is as follows:

in the formula (17), the compound represented by the formula (I),

is the voltage value of the DC power supply E, j is an imaginary number symbol, omega is the angular frequency of system operation, pi is the circumferential rate, M is the transmitting coil L_PAnd a receiving coil L_sMutual inductance between, I_BIs the current value set during constant current charging,

is a receiving coil L_sThe current of (2).

The compensation capacitor C is obtained from the equations (11), (16) and (17)_fCapacity of

Determined by equation (18):

in the formula (18), the reaction mixture,

is the voltage value of the direct current power supply E, omega is the angular frequency of the system work, pi is the circumferential rate,

for compensating inductance L_fInductance value of, V_BSetting the charging voltage for constant-voltage charging, I_BThe current value is set during constant current charging.

The compensation capacitance C can be obtained from the equations (17) and (18)_SVCapacity of

Determined by equation (20):

in the formula (19), the compound represented by the formula (I),

is the voltage value of the DC power supply E, omega is the angular frequency of the system, pi is the circumferential rate, V_BSetting the charging voltage for constant-voltage charging, I_BThe current value is set during constant current charging.

In the constant voltage charging mode of the wireless charging system, in order to enable the LCC structure at the receiving side to be in a complete resonance state, the conditions required to be met by the constant voltage compensation capacitor at the receiving side are as follows:

in the formula (20), ω is the angular frequency of system operation, j is the imaginary symbol,

is a receiving coil L_sThe inductance value of (a) is set,

compensating the capacitance C for the receiving side_sThe capacity value of (a) is,

to compensate for capacitance C_SVThe capacity value of (c).

The receiving side compensation capacitor C can be obtained from the equations (19) and (20)_sCapacity of

Determined by equation (21):

in the formula (21), pi is the circumferential ratio, omega is the angular frequency of system operation, I_BIs the current value set during constant current charging,

is the value of the voltage of the direct current power supply E,

is a receiving coil L_sInductance value of, V_BThe charging voltage is set for constant voltage charging.

When the charging system is in constant current charging, the receiving side is in a series structure, and in order to enable the system to be in a complete resonance state, the relation formula that each electric quantity of the receiving side needs to meet is as follows:

in the formula (22), j is an imaginary symbol, ω is the system operating angular frequency,

is a receiving coil L_sThe inductance value of (a) is set,

to compensate for electricityFeeling L_fThe inductance value of (a) is set,

compensating the capacitance C for the receiving side_sThe capacity value of (a) is,

compensating the capacitance C for the receiving side_fThe capacity value of (a) is,

compensating the capacitor C for constant current_SCThe capacity value of (c).

According to the formula (22), the constant current compensation capacitor C_SCCapacity of

Determined by equation (23):

in the formula (23), pi is a circumferential ratio, I_BIs the current value set during constant current charging,

is the voltage value of the direct current power supply E, omega is the angular frequency of the system,

for compensating inductance L_fThe inductance value of (a) is set,

for compensating inductance L_sInductance value of, V_BThe charging voltage is set for constant voltage charging.

In summary, when the controller K controls the first switch S₁Closed, second change-over switch S₂The charging system is switched off and works in a constant voltage mode; when the controller K controls the first switch S₁Off, the second change-over switch S₂And when the charging system is closed, the charging system works in a constant current mode.

Compared with the prior art, the invention has the advantages that:

1. the constant-current and constant-voltage output of the receiving side can be realized by adjusting the compensation structure of the receiving side through the change-over switch without adjusting the working frequency or the pulse width of the inverter, and the system can output constant current and voltage irrelevant to a load under the same working frequency, thereby meeting the requirements of initial constant-current charging and later constant-voltage charging of the battery. When the system works in a constant-current mode and a constant-voltage mode, complete resonance can be realized, and the system efficiency is high.

2. Compensation inductance L_fAnd a compensation capacitor C_fThe equivalent inductance and the compensation inductance L are formed in series_fHigh degree of freedom in design by adding compensation L_fThe inductance value of the rectifier filter can realize the continuity of the input current of the rectifier filter in a wider load range, and avoid the reduction of the output voltage caused by the interruption of the input current of the rectifier filter during constant voltage charging, so that the charging voltage is kept unchanged.

Drawings

The invention is further described with reference to the following figures and detailed description.

FIG. 1 is a schematic diagram of the circuit structure of the present invention;

FIG. 2 is a schematic diagram of rectifier bridge input voltage and current when the rectifier filter input current is distorted;

FIG. 3 is an equivalent circuit diagram in the constant voltage mode of the present invention;

fig. 4 is an equivalent circuit diagram in the constant current mode of the present invention.

Detailed Description

As shown in fig. 1, the constant current and constant voltage induction type wireless charging system based on the secondary structure of the invention is composed of a transmitting part and a receiving part; the transmitting part comprises a direct current power supply E, a high-frequency inverter H and a primary compensation capacitor C which are sequentially connected in series_pAnd a primary transmitting coil L_P(ii) a The receiving part comprises receiving coils L connected in series in sequence_sA switching circuit I and a compensation inductor L_fA rectifier filter R and a load II, characterized by a receiving coil L_sAnd a compensation capacitor C_sAnd a compensation capacitor C_fAnd a compensation inductance L_fAnd the rectifier filters R are connected in series in sequence; constant current compensation capacitor C_SCAnd a first switch S₁One end of the series capacitor is connected with a compensation capacitor C_sAnd a compensation capacitor C_fIs connected to the common point of the receiving coil L and the other end is connected to the receiving coil L_sIs connected with the common point of the rectifier filter R; constant voltage compensation capacitor C_SVAnd a second change-over switch S₂One end of the series capacitor is connected with a compensation capacitor C_sAnd a receiving coil L_sIs connected to the common point of the other end of the first and second inductors, and the other end of the second inductor is connected to the compensation inductor L_fAnd a compensation capacitor C_fAre connected. First change-over switch S₁And a first switch S₂Is connected with the controller K.

Fig. 2 is a schematic diagram of input voltage and current of a rectifier bridge when input current of a rectifier filter is distorted. In FIG. 2, i_mIdeally, the input current i of the rectifier filter_rIs the actual input current of the current rectifier, omega is the angular frequency of system operation, u_rTheta is the lag angle between the actual input current and the ideal current phase of the rectifier filter,

for the input voltage u of the rectifier filter_rZero crossing and i_rAnd the phase difference between the discontinuous critical points is the discontinuous angle of the input current of the rectifier filter.

Fig. 3 is an equivalent circuit of the charging system of the present invention in the constant voltage operation mode. In the context of figure 3, it is shown,

is the fundamental component of the inverter output voltage, L_PTransmitting coil, C_pCompensation capacitance, L_sTo receive coils, C_sCompensating the capacitance for the receiving side, C_SVConstant voltage compensation capacitor, L_fTo compensate for inductance, C_fIn order to compensate for the capacitance,

is a transmitting coil L_PThe current of (a) is measured,

is a receiving coil L_sCurrent of R_eIs the equivalent alternating current load of the battery.

Fig. 4 is an equivalent circuit of the charging system in the constant current operating mode. In the context of figure 4, it is shown,

is the fundamental component of the inverter output voltage, L_PTransmitting coil, C_pCompensation capacitance, L_sTo receive coils, C_sCompensating the capacitance for the receiving side, C_SCConstant current compensation capacitor, L_fTo compensate for inductance, C_fIn order to compensate for the capacitance,

is a transmitting coil L_PThe current of (a) is measured,

is a receiving coil L_sCurrent of R_eIs the equivalent alternating current load of the battery.

In this embodiment:

the first change-over switch S₁Closed, second change-over switch S₂The system is disconnected to realize constant voltage output; the first change-over switch S₁Off, the second change-over switch S₂And when the charging system is closed, the constant current output is realized. In order to realize the input current continuity of the rectifier filter in a wide load range, the compensation inductor L_fInductance value of

Determined by formula (1):

in the formula (1), pi is the circumferential ratio, omega is the angular frequency of system operation, V_BVoltage value set for constant voltage charging of battery, I_BThe current value is set during constant current charging.

The transmitting coil L_PAnd a receiving coil L_sThe mutual inductance M therebetween is determined by equation (2):

in the formula (2), the reaction mixture is,

is the voltage value of the DC power supply E, pi is the circumferential rate, omega is the angular frequency of system operation, I_BThe current value is set when the battery is charged with constant current.

The compensation capacitor C_fCapacitance value of

Determined by equation (3):

in the formula (3), pi is the circumferential ratio, omega is the angular frequency of system operation, I_BIs the current value set during constant current charging,

is the value of the voltage of the direct current power supply E,

for compensating inductance L_fSensitivity value of V_BThe voltage value is set when the battery is charged at constant voltage.

The compensation capacitor C_sCapacitance value of

Determined by equation (4):

in the formula (4), pi is the circumferential ratio and omega is the systemOperating angular frequency, I_BThe current value set when the battery is in constant current charging,

is the value of the voltage of the direct current power supply E,

is a receiving coil L_sSensitivity value of V_BThe voltage value is set when the battery is charged at constant voltage.

The constant voltage compensation capacitor C_SVCapacitance value of

Determined by equation (5):

in the formula (5), pi is the circumferential ratio, I_BThe current value set for constant current charging of the battery is omega, the angular frequency of system operation, V_BThe voltage value is set when the battery is charged at constant voltage.

The constant current compensation capacitor C_SCCapacitance value of

Determined by equation (6):

in the formula (6), pi is the circumferential ratio, omega is the angular frequency of system operation, I_BThe current value set when the battery is in constant current charging,

is the value of the voltage of the direct current power supply E,

is a receiving coil L_sThe inductance value of (a) is set,

for compensating inductance L_fInductance value of, V_BThe voltage value is set when the battery is charged at constant voltage.

The controller K controls the first switch S₁Off, second change-over switch S₂When the wireless charging system is closed, the wireless charging system works in a constant current mode, and constant current is output to a load on a receiving side, namely, the set constant charging current I is provided for the battery_B(ii) a The method is suitable for the constant current charging stage at the initial stage of battery charging.

The controller K controls the first switch S₁Closed, second change-over switch S₂When the charging system is disconnected, namely the charging system works in a constant voltage mode, constant voltage is output to the load at the receiving side, namely the set constant charging voltage V is provided for the battery_B(ii) a The method is suitable for the constant voltage charging stage in the later charging stage of the battery.

Claims (3)

1. A constant-current constant-voltage induction type wireless charging system based on a transformer structure is composed of a transmitting part and a receiving part; the transmitting part comprises a direct current power supply E, a high-frequency inverter H and a primary compensation capacitor C which are sequentially connected in series_pAnd a primary transmitting coil L_p(ii) a The receiving part comprises receiving coils L connected in series in sequence_sA switching circuit I and a compensation inductor L_fRectifier filter R and load II, its characterized in that: receiving coil L_sAnd a compensation capacitor C_sAnd a compensation capacitor C_fAnd a compensation inductance L_fAnd the rectifier filters R are connected in series in sequence; constant voltage compensation capacitor C_SVAnd a first switch S₁One end of the series capacitor is connected with a compensation capacitor C_sAnd a compensation capacitor C_fIs connected with a common point of the constant voltage compensation capacitor C_SVAnd a first switch S₁The other end of the series connection is connected with a receiving coil L_sIs connected with the common point of the rectifier filter R; constant current compensation capacitor C_SCAnd a second change-over switch S₂One end of the series capacitor is connected with a compensation capacitor C_sAnd a receiving coil L_sIs connected with a constant current compensation capacitor C_SCAnd a second change-over switchS₂The other end of the series connection and the compensation inductor L_fAnd a compensation capacitor C_fAre connected; first change-over switch S₁And a second change-over switch S₂The control end of the controller K is connected with the controller K; the wireless charging system can realize continuous input current of the rectifier filter in a wide load range, so that the output voltage of the system is kept unchanged during constant voltage charging of the wireless charging system.

2. The wireless charging system of claim 1, wherein: the first change-over switch S₁Closed, the second change-over switch S₂When the wireless charging system is disconnected, the wireless charging system realizes constant voltage output; the first change-over switch S₁Off, the second change-over switch S₂And when the wireless charging system is closed, the constant current output is realized.

3. The wireless charging system according to claim 1 or 2, wherein: in order to ensure that the input current of the rectifier is continuous before the charging is cut off to the current in the constant-voltage charging process, the compensation inductor L_fInductance value of

Determined by formula (1):

the transmitting coil L_PAnd a receiving coil L_sThe mutual inductance therebetween is determined by equation (2):

the compensation capacitor C_fCapacitance value of

Determined by equation (3):

the compensation capacitor C_sCapacitance value of

Determined by equation (4):

the constant voltage compensation capacitor C_SVCapacitance value of

Determined by equation (5):

the constant current compensation capacitor C_SCCapacitance value of

Determined by equation (6):

in the formulae (1), (2), (3), (4), (5), (6),

is the output voltage value of the DC power supply E, pi is the circumferential rate, omega is the angular frequency of system operation, I_BCurrent value, V, set for constant-current charging of the battery_BA voltage value set when the battery is charged at a constant voltage,

to compensate for capacitance C_fThe capacitance value of (a) is set,

compensating the capacitor C for constant voltage_SVThe capacitance value of (a) is set,

compensating the capacitor C for constant current_SCThe capacitance value of (a) is set,

to compensate for capacitance C_SThe capacitance value of (a) is set,

is a receiving coil L_sThe inductance value of (c).

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