CN107565707B - Optimal switching design method for magnetic coupling electric energy transmission coil - Google Patents

Abstract

The invention discloses an optimal switching design method for a magnetic coupling power transmission coil, and belongs to the technical field of wireless power transmission equipment. The inventionThe key points of the technical scheme are as follows: determining the size of a one-way coil of a receiving end according to a charging target, and determining the sizes of a forward coil and a direction coil of a transmitting end according to a power supply; determining the turn ratio between a forward coil and a reverse coil of a transmitting end according to a mutual inductance formula, adjusting the turn number of the reverse coil of the transmitting end, and selecting a proper turn number according to the flatness of a mutual inductance change curve along with the transmission distance between a forward-reverse series coil of the transmitting end and a one-way coil of a receiving end; then two adjustable capacitors C are used₁、C₂And the transmitting end forward and reverse series coils and the receiving end unidirectional coil are tuned to the used working frequency. The forward and reverse series coils in a short distance are used as the transmitting coil of the WPT/MRC system, so that the frequency splitting phenomenon can be effectively inhibited; the forward coil is used as a transmitting coil of the WPT/MRC system when the distance is long, and high-efficiency transmission of the system is kept.

Description

Optimal switching design method for magnetic coupling electric energy transmission coil

Technical Field

The invention belongs to the technical field of wireless power transmission equipment, and particularly relates to an optimal switching design method of a magnetic coupling power transmission coil.

Background

With the gradual improvement of living standard, the traditional wired electric energy transmission mode seriously affects the service life and the electricity utilization safety of power supply equipment due to the problems of friction, aging, easy generation of electric sparks and the like, and can not meet the requirements of people on high-quality living standard. The wireless power transmission mode is a more flexible, convenient and safe energy transmission mode, and is widely concerned at home and abroad.

In 2007, MIT scientists successfully lighted a 60W bulb within 2m distance by using the magnetic coupling resonance wireless power transmission (WPT/MRC) theory, and the transmission efficiency reaches about 50%. The wireless power transmission technology makes great contribution in medium and long distance energy transmission. In recent years, the magnetic coupling resonant wireless power transmission mode has been a hot point of research at home and abroad. However, in the magnetic coupling resonance type wireless power transmission, when the distance between the transmitting coil and the receiving coil is less than a certain critical value, the transmission efficiency of the system at the resonance frequency is no longer the maximum value, but peaks at two frequency points at both ends of the resonance frequency point, which is called frequency splitting.

In order to suppress frequency splitting, methods of frequency tracking, impedance matching, changing the coil structure, and the like may be employed. In the frequency tracking technology, a series of complex circuits such as a high-frequency current detector, a differential amplifier, a phase compensator, a phase-locked loop and the like are added in a WPT/MRC system to realize tracking control of the resonant frequency of a transmitting loop, so that frequency splitting is inhibited. However, these additional circuits complicate the system and also consume additional energy. The impedance matching method is to suppress frequency splitting using an adjustable impedance matching network in the WPT/MRC system, but requires an inverter circuit, a feedback circuit, a control circuit, and the like to adjust matching impedance according to a transmission distance. Furthermore, frequency splitting can also be suppressed by changing the structure of the coil. However, by changing the structure of the coil, the frequency splitting should be suppressed during short-distance transmission, and it is ensured that the transmission efficiency of the system is not reduced during long-distance transmission.

Disclosure of Invention

The invention provides an optimal switching design method of a magnetic coupling electric energy transmission coil, which aims to realize that no additional complex circuit is added in a system and redundant energy is consumed, and meanwhile, the frequency splitting occurring in WPT/MRC can be effectively inhibited in a close range, the transmission efficiency of the system is improved, and further, the high-efficiency transmission is kept in a long range.

The invention adopts the following technical scheme that the optimal switching design method of the magnetic coupling electric energy transmission coil is characterized in that the device comprises a signal generator, a power amplifier, a transmitting end forward and reverse series coil consisting of an inverting coil and a forward coil which are coaxially arranged inside and outside, a receiving end unidirectional coil, a switch g and an adjustable capacitor C₁An adjustable capacitor C₂And the load, wherein the transmitting terminal forward and reverse series coil and the receiving terminal unidirectional coil are arranged coaxially after a space is reserved between the transmitting terminal forward and reverse series coil and the receiving terminal unidirectional coil, the signal output end of the signal generator is connected with the signal input end of the power amplifier, and the forward output end of the power amplifier is connected with the adjustable capacitor C₁Is connected to an adjustable capacitor C₁Another end of (1)One end of the unidirectional coil is connected with the positive input end of the load, and the other end of the unidirectional coil is connected with the adjustable capacitor C₂Is connected to an adjustable capacitor C₂The other end of the first switch is connected with the negative input end of the load;

the specific design process is as follows: determining the size of the receiving end one-way coil, namely the radius and the number of turns of the receiving end one-way coil according to the size of a charging target in practical application; determining the radius of a forward coil and a reverse coil of a transmitting terminal by an excitation source; determining the turn ratio between the forward coil and the backward coil of the transmitting terminal according to a mutual inductance formula, wherein the radius of the unidirectional coil of the receiving terminal is set as r_RThe number of turns is n_RSetting the radius of the forward coil of the forward and reverse series coils of the transmitting terminal as r_T ^fRadius of the reverse coil is r_T ^rAnd (3) according to a mutual inductance formula between two single-turn circular coils:

and (3) solving the mutual inductance between the forward and reverse series coils of the transmitting terminal and the unidirectional coil of the receiving terminal:

in the formula, mu₀Is a vacuum permeability of r₁And r₂The radii of the two single-turn round coils are respectively, d is the distance between the two single-turn round coils, and K (k) and E (k) are respectively the first type and the second type of elliptic integrals; n is_T ^fAnd n_T ^rNumber of turns, n, of the forward and reverse coils, respectively_RIs the number of turns r of the receiving end unidirectional coil_T ^fAnd r_T ^rRadius of the forward and reverse coils, r, respectively_RRadius of the receiving end unidirectional coil, D_ijIs the i-th turn of the forward coil or the reverse coilAnd the distance between the jth turn of the receiving end unidirectional coil, D is the distance between the forward coil or the reverse coil and the central point of the receiving end unidirectional coil, a is the radius of the lead, p is the pitch, and the pitch p of the close-wound coil is 0 and can be ignored;

by differentiating M (D) with respect to D, the formula:

determining the position D of a frequency split point when the forward coil is used alone as a transmitting coil_sChanging D to D₁＝D_sThe number of turns of the reverse coil can be obtained by substituting the equation;

changing the number of turns of the reverse coil according to a formula

Determining the flatness degree of the mutual inductance curve between the transmitting end forward and reverse series coils and the receiving end one-way coil along with the change of the distance, wherein the smaller v is, the flatter the mutual inductance change curve is, wherein the number of turns of the transmitting end reverse coil corresponding to the flattest mutual inductance change curve between the transmitting end forward and reverse series coils and the receiving end one-way coil along with the change of the transmission distance is selected as the optimal design number of turns, and in the formula, D is₀Is the initial distance between the forward and reverse series coils of the transmitting terminal and the unidirectional coil of the receiving terminal, D₁The distance between the two coils is the maximum value of mutual inductance between the transmitting end forward and reverse series coils and the receiving end unidirectional coil;

making a curve that the efficiency of the WPT/MRC system changes with the distance at the working frequency when the forward and reverse series coils are used as transmitting coils and a curve that the efficiency of the WPT/MRC system changes with the distance at the working frequency when the forward coil is used as the transmitting coil, and solving the problem that when the two curves are intersected, the transmission distance is D_m；

When the transmission distance is less than D_mWhen the WPT/MRC system with the forward and reverse series coils as the transmitting coil has higher transmission efficiency than the WPT/MRC system with the forward coil as the transmitting coil, so that the transmission efficiency is higherForward and reverse series coils are used as transmitting coils of the WPT/MRC system to inhibit frequency splitting and realize high-efficiency transmission of the system; when the transmission distance is greater than D_mWhen the system is used, the transmission efficiency of the WPT/MRC system with the forward and reverse series coils as the transmitting coils is lower than that of the WPT/MRC system with the forward coil as the transmitting coil, so that the reverse coil is short-circuited by closing the switch g, and the forward coil is used as the transmitting coil of the WPT/MRC system, so that the high-efficiency transmission of the system is kept;

then using an adjustable capacitor C₁And an adjustable capacitor C₂And tuning the transmitting end forward and reverse series coil and the receiving end unidirectional coil to the used working frequency to complete the design of the transmitting end forward and reverse series coil of the magnetic coupling resonance high-efficiency electric energy transmission coil for wireless electric energy transmission.

Preferably, the transmitting end forward coil, the transmitting end reverse coil and the receiving end unidirectional coil are all spiral circular coils, spiral rectangular coils or spiral elliptical coils.

More preferably, the radius r of the receiving-end unidirectional coil_RAnd n number of turns_RThe set standard of (2) is determined according to an actual charging target; radius r of forward coil of transmitting terminal_T ^fAnd reverse coil radius r_T ^rIs determined according to the signal source.

The invention has the following beneficial effects: when the system is in a short distance, the forward and reverse series coils are used as the transmitting coil of the WPT/MRC system, so that the frequency splitting phenomenon can be effectively inhibited, and the transmission efficiency of the system is improved; and when the distance is long, the forward coil is used as a transmitting coil of the WPT/MRC system, so that the high-efficiency transmission of the system is kept.

Drawings

FIG. 1 is a WPT/MRC system architecture diagram;

FIG. 2 is an equivalent circuit diagram of a WPT/MRC system;

FIG. 3 is a simulation diagram of mutual inductance between the unidirectional coil of the receiving end and the forward coil with the number of turns varying with distance;

FIG. 4 is a simulation diagram of mutual inductance between the receiver-side unidirectional coil and the reverse coil when the number of turns of the reverse coil changes with distance;

FIG. 5 is a diagram showing a simulation curve of mutual inductance between the transmitting end forward and backward series coils and the receiving end unidirectional coil with distance variation;

FIG. 6 is a schematic diagram of a selected optimal design;

fig. 7 is a simulation diagram of transmission efficiency and frequency of a wireless power transmission system using a forward coil as a transmitting coil and a distance between the transmitting coil and the receiving coil;

fig. 8 is a simulation diagram of the transmission efficiency and the frequency of the wireless power transmission system using forward and reverse series coils as transmitting coils and the distance between the transmitting and receiving coils;

fig. 9 is a schematic diagram comparing transmission efficiency of a wireless power transmission system with forward and reverse series coils as transmitting coils and a wireless power transmission system with a forward coil as a transmitting coil with distance variation;

fig. 10 is a schematic diagram showing the transmission efficiency of a wireless power transmission system in which a forward coil and a reverse coil are connected in series at a short distance and a forward coil is used as a transmitting coil at a long distance, which varies with the distance.

Detailed Description

The present invention is described in further detail below with reference to examples, but it should not be construed that the scope of the above subject matter of the present invention is limited to the following examples, and that all the technologies realized based on the above subject matter of the present invention belong to the scope of the present invention.

Examples

The optimal switching design method of the magnetic coupling electric energy transmission coil is realized by the following steps:

step one, during short-distance transmission, a transmitting end of the WPT/MRC system is a forward and reverse series coil, namely the forward and reverse series coil is used as a transmitting coil, and a receiving end is a unidirectional coil, namely the unidirectional coil is used as a receiving coil; the forward and reverse series coils consist of a forward coil and a reverse coil, the forward coil is outside, the reverse coil is embedded in the forward coil, and the directions of currents flowing through the forward coil and the reverse coil are opposite; the forward coil, the reverse coil and the unidirectional coil are all spiral circular coils; the transmitting end forward and reverse series coil and the receiving end one-way coil are coaxially arranged, and the receiving end one-way is setRadius of the coil being r_RThe number of turns is n_RSetting the radius of the forward coil of the forward and reverse series coils formed by the transmitting ends as r_T ^fRadius of the reverse coil is r_T ^r；

Step two, according to a mutual inductance formula between two single-turn circular coils:

in the formula, mu₀Is the magnetic permeability of vacuum (4 pi x 10)^-7H/m)，r₁，r₂The radii of the two single-turn circular coils are respectively, D is the distance between the two coils, and K (k) and E (k) are respectively the first type and the second type of elliptic integrals;

obtaining the mutual inductance between the transmitting end forward coil and the receiving end unidirectional coil:

and mutual inductance between the reverse coil and the receiving end unidirectional coil:

then, the mutual inductance between the transmitting end forward and reverse series coil and the receiving end unidirectional coil is obtained:

in the formula, n_T ^fAnd n_T ^rNumber of turns, n, of the forward and reverse coils, respectively_RIs the number of turns of the receiving coil, r_T ^fAnd r_T ^rRadius of the forward and reverse coils, r, respectively_RThen the radius of the receiving coil, D_ijIs the distance between the ith turn of the forward or reverse coil and the jth turn of the receive coil, a is the wire radius and p is the pitch (the close-wound coil pitch p is 0, negligible).

Step three, obtaining a formula by differentiating M (D) with respect to D:

determining the position D of a frequency split point when the forward coil is used alone as a transmitting coil_SChanging D to D₁＝D_SThe number of turns of the counter coil can be obtained by substituting the above equation for/2.

Step four, changing the number of turns of the reverse coil according to a formula

Determining the flatness degree of a mutual inductance change-with-distance curve between the transmitting end forward and reverse series coil and the receiving end unidirectional coil, wherein the smaller v is, the flatter the mutual inductance change-with-distance curve is; through a series of comparison, the number of turns of the reverse coil calculated by a formula is an optimal value.

In the formula, D₀Is the initial distance between the forward and reverse series coils of the transmitting terminal and the unidirectional coil of the receiving terminal, D₁The maximum value for mutual inductance is the distance between the two coils.

Step five, making a curve that the efficiency of the WPT/MRC system changes with the distance at the working frequency when the forward and reverse series coils are used as transmitting coils and a curve that the efficiency of the WPT/MRC system changes with the distance at the working frequency when the forward coil is used as the transmitting coil; when two curves are intersected, the transmission distance is D_m。

Step six, when the transmission distance is less than D_mWhen the WPT/MRC system with the forward and reverse series coils as the transmitting coils is used, the transmission efficiency of the WPT/MRC system with the forward and reverse series coils as the transmitting coils is higher than that of the WPT/MRC system with the forward coil as the transmitting coil; when the transmission distance is greater than D_mAnd when the WPT/MRC system with the forward and reverse series coils as the transmitting coil is used, the transmission efficiency is lower than that of the WPT/MRC system with the forward coil as the transmitting coil.

Step seven, when the transmission distance is less than D_mIn the forward and reverse directionsThe series coil is used as a transmitting coil of the WPT/MRC system and is used for inhibiting frequency splitting and realizing high-efficiency transmission of the system; when the transmission distance is greater than D_mAnd in the process, the reverse coil is short-circuited, and the forward coil is used as a transmitting coil of the WPT/MRC system, so that the high-efficiency transmission of the system is kept.

And step eight, tuning the receiving and transmitting coil to the used working frequency respectively by using the two adjustable capacitors, and finishing the optimal switching design method applied to the magnetic coupling electric energy transmission coil.

Radius r of the receiving coil_RAnd n number of turns_RThe set standard of (2) is determined according to an actual charging target; forward coil radius r of forward and backward series coil forming transmitting terminal_T ^fAnd reverse coil radius r_T ^rIs determined according to the signal source.

Number n of forward coil turns forming forward and reverse series coil of transmitting terminal_T ^fAnd the number n of reverse coil turns_T ^rThe setting method is determined according to the flatness of a mutual inductance change curve along with the distance between the transmitting end forward and reverse series coils and the receiving end unidirectional coil.

A design method of a wireless power transmission coil for inhibiting frequency splitting comprises a transmitting coil (a forward and reverse series coil consisting of a forward coil and a reverse coil), a receiving coil (a one-way coil), and an adjustable capacitor C₁And an adjustable capacitor C₂(ii) a The forward coil, the reverse coil and the unidirectional coil are all spiral circular coils;

the signal output end of the signal generator is connected with the signal input end of the power amplifier; the positive output terminal of the power amplifier and the adjustable capacitor C₁Is connected with one end of the connecting rod; the adjustable capacitor C₁The other end of the positive coil is connected with one end of the positive coil; the other end of the forward coil is connected with one end of the reverse coil and one end of the switch g respectively; the other end of the switch g is connected with a negative power output end of the power amplifier; the other end of the reverse coil is connected with a negative power output end of the power amplifier;

the transmitting end forward and reverse series coil and the receiving end unidirectional coil are relatively coaxially arranged, and the transmitting end forward and reverse series coil and the receiving end unidirectional coil are relatively coaxially arrangedOne end of the receiving end one-way coil is connected with a positive input terminal of the load; the other end of the receiving end one-way coil and the adjustable capacitor C₂Is connected to the adjustable capacitor C₂The other end of which is connected to the negative terminal of the load.

For a WPT/MRC system with a two-coil configuration, the system configuration is as shown in fig. 1, where a signal is generated from a signal generator, passed through a power amplifier, transmitted by a transmitting coil, received by a receiving coil, and delivered to a load.

Figure 2 is an equivalent circuit of the WPT/MRC system, and the coils interact with each other through magnetic field resonance coupling, and the strength of the coupling is measured by mutual inductance M.

The transmission characteristic of the magnetic coupling resonance type wireless energy transmission system can be represented by a transmission coefficient S₂₁The transmission efficiency is represented by η.

η＝|S₂₁|²×100％ (2)

When the system is operated at the coil resonance frequency, the transmission coefficient S₂₁Can be simplified into the formula (3):

as can be seen from equation (3), the transmission coefficient S₂₁Is a function of mutual inductance and frequency, so that a flat efficiency change curve is obtained under a fixed working frequency, and the flat mutual inductance change curve can be realized. Therefore, it is very important for the coil to be optimally designed.

As shown in fig. 3, using a forward coil as the transmitting coil, the mutual inductance between the forward coil and the one-way coil varies greatly with distance at a close distance.

Therefore, a reverse coil can be introduced at the transmitting end to suppress drastic mutual inductance variation between the forward coil and the one-way coil in a short distance.

The mutual inductance between two coaxial single turn circular coils can be represented by equation (4):

in the formula, mu₀Is the magnetic permeability of vacuum (4 pi x 10)^-7H/m)，r₁,r₂The radii of the two single-turn circular coils, d the distance between the two single-turn circular coils, and K (k) and E (k) are the first and second elliptical integrals, respectively.

The mutual inductance between the forward coil and the receiving-end unidirectional coil can be expressed by equation (5):

in the formula, n_T ^fIs the number of turns of the forward coil, n_RIs the number of turns r of the receiving end unidirectional coil_T ^fIs the radius of the forward coil, r_RThen the radius of the receiver's one-way coil, D_ijThe distance between the ith turn of the forward coil and the jth turn of the receiving end unidirectional coil is shown, and D is the distance between the center points of the forward coil and the receiving end unidirectional coil.

Fig. 3 is a schematic diagram showing the mutual inductance between the unidirectional coil at the receiving end and the forward coil when the number of turns of the forward coil changes.

The mutual inductance between the reverse coil and the receiving-end unidirectional coil can be expressed by equation (6):

fig. 4 is a schematic diagram showing the mutual inductance between the receiving end one-way coil and the reverse coil when the number of turns of the reverse coil changes according to the distance.

The mutual inductance between the forward-reverse series coil and the receiving-end unidirectional coil can be expressed by equation (7):

in the formula, n_T ^rIs the number of turns of the counter-coil, n_RIs the number of turns r of the receiving end unidirectional coil_T ^rIs the radius of the counter-coil, r_RThen the radius of the receiver's one-way coil, D_ijIs the distance between the ith turn of the reverse coil and the jth turn of the receiving end unidirectional coil, D is the distance between the center points of the reverse coil and the receiving end unidirectional coil, a is the radius of the lead, and p is the pitch (the pitch p of the close-wound coil is 0 and can be ignored).

Fig. 5 is a schematic diagram showing the mutual inductance between the forward and reverse series coils and the receiving end unidirectional coil as a function of distance.

Obtaining formula (8) by a differential division of formula (7):

i.e. the number of turns of the counter coil is found.

Varying the number of turns of the counter coil according to equation (9):

determining the flatness degree of a mutual inductance change-with-distance curve between the transmitting end forward and reverse series coil and the receiving end unidirectional coil, wherein the smaller v is, the flatter the mutual inductance change-with-distance curve is; through a series of comparison, the number of turns of the reverse coil calculated by a formula is an optimal value. As shown in fig. 6.

Making a curve that the efficiency of the WPT/MRC system changes with the distance at the working frequency when the forward and reverse series coils are used as transmitting coils and a curve that the efficiency of the WPT/MRC system changes with the distance at the working frequency when the forward coil is used as the transmitting coil; when two curves are intersected, the transmission distance is D_m。

When the transmission distance is less than D_mWhen the WPT/MRC system with the forward and reverse series coils as the transmitting coils is used, the transmission efficiency of the WPT/MRC system with the forward and reverse series coils as the transmitting coils is higher than that of the WPT/MRC system with the forward coil as the transmitting coil; when the transmission distance is greater than D_mTime, forward and reverse series lineThe transmission efficiency of the WPT/MRC system with the coil as the transmitting coil is lower than that of the WPT/MRC system with the forward coil as the transmitting coil.

When the transmission distance is less than D_mWhen the WPT/MRC system is used, a forward and reverse series coil is used as a transmitting coil of the WPT/MRC system and is used for inhibiting frequency splitting and realizing high-efficiency transmission of the system; when the transmission distance is greater than D_mAnd in the process, the reverse coil is short-circuited, and the forward coil is used as a transmitting coil of the WPT/MRC system, so that the high-efficiency transmission of the system is kept.

According to an equivalent circuit diagram (shown in figure 2) of the WPT/MRC system and formulas (1) and (2), a simulation schematic diagram (figure 7) of the WPT/MRC system with a forward coil as a transmitting coil and the distance between the transmitting coil and the receiving coil and the working frequency and a simulation schematic diagram (figure 8) of the WPT/MRC system with a forward-reverse series coil as the transmitting coil and the distance between the transmitting coil and the receiving coil and the working frequency are drawn. By comparing fig. 7 and fig. 8, it can be found that the WPT/MRC system with the forward coil as the transmitting coil has obvious frequency splitting in a short distance, because the mutual inductance between the two coils changes dramatically with the decrease of the distance between the forward coil and the receiving end one-way coil, resulting in the system being in an over-coupled state and frequency splitting; in the WPT/MRC system with the forward and reverse series coils as the transmitting coils, the violent change of mutual inductance between the forward coil and the receiving end one-way coil is restrained due to the existence of the reverse coil, and the frequency splitting phenomenon is prevented.

By comprehensively comparing fig. 7 and fig. 8, it can be obtained that the wireless power transmission system using the forward and reverse series coils as the transmitting coils can well inhibit the occurrence of frequency splitting.

Fig. 9 is a schematic diagram showing comparison of transmission efficiency of a wireless power transmission system with forward and reverse series coils as a transmitting coil and a forward coil as a transmitting coil according to distance variation; it can be seen that when the transmission distance is less than D_mWhen the WPT/MRC system with the forward and reverse series coils as the transmitting coils is used, the transmission efficiency of the WPT/MRC system with the forward and reverse series coils as the transmitting coils is higher than that of the WPT/MRC system with the forward coil as the transmitting coil; when the transmission distance is greater than D_mWPT/MRC system transmission with forward and reverse series coils as transmitting coilsThe transmission efficiency is lower than that of a WPT/MRC system with a forward coil as a transmitting coil. Then may be at D_mThe forward and reverse series coils and the forward coil are switched at the point, so that the forward and reverse series coils and the forward coil are respectively used as transmitting coils under different conditions, and high-efficiency transmission of the system is realized.

Fig. 10 shows the system efficiency as a function of distance when the forward and reverse series coils and the forward coil are switched to be the transmitting coil under different conditions. When the system is in a close range, the forward and reverse series coils are used as transmitting coils, and the system performs high-efficiency transmission; the forward coil acts as a transmit coil at long distances to maintain efficient transmission of the system.

Summarizing the manufacturing of the forward and reverse series coils and the switching method thereof, the following design steps can be summarized:

1. determining the size of a receiving coil according to a charging target, and determining the sizes of a forward coil and a direction coil of a transmitting terminal according to a power supply;

2. obtaining mutual inductance between the forward and reverse series coils and the receiving coil, namely obtaining (7), obtaining (8) through differentiation of the (7), obtaining the turn ratio of the forward coil and the reverse coil, adjusting the turn number of the forward coil and the reverse coil, and selecting proper turn number according to the flatness degree of change of a mutual inductance curve between the forward and reverse series coils and the receiving coil;

3. during short-distance transmission, a forward and reverse series coil is used as a transmitting coil; when the transmission distance exceeds a certain value, the reverse coil is short-circuited at the transmitting end, namely the forward coil is used as the transmitting coil; the transceiver coil is tuned to the operating frequency used by the tunable capacitor.

Theoretical calculation shows that when the short-distance energy is transmitted, the forward and reverse series coils are used as transmitting coils, so that the WPT/MRC system frequency splitting phenomenon can be effectively inhibited, and the transmission efficiency of the system is improved; when the long-distance energy is transmitted, the forward coil is used as a transmitting coil, so that the WPT/MRC system can be kept to transmit energy efficiently.

The foregoing embodiments illustrate the principles, principal features and advantages of the invention, and it will be understood by those skilled in the art that the invention is not limited to the foregoing embodiments, which are merely illustrative of the principles of the invention, and that various changes and modifications may be made therein without departing from the scope of the principles of the invention.

Claims (1)

1. The optimal switching design method of the magnetic coupling electric energy transmission coil is characterized in that the device comprises a signal generator, a power amplifier, a transmitting end forward and reverse series coil consisting of an inverting coil and a forward coil which are coaxially arranged inside and outside, a receiving end unidirectional coil, a switch g and an adjustable capacitor C₁An adjustable capacitor C₂And the load, wherein the transmitting terminal forward and reverse series coil and the receiving terminal unidirectional coil are arranged coaxially after a space is reserved between the transmitting terminal forward and reverse series coil and the receiving terminal unidirectional coil, the signal output end of the signal generator is connected with the signal input end of the power amplifier, and the forward output end of the power amplifier is connected with the adjustable capacitor C₁Is connected to an adjustable capacitor C₁The other end of the unidirectional coil is connected with the positive input end of the load, and the other end of the unidirectional coil is connected with the adjustable capacitor C₂Is connected to an adjustable capacitor C₂The other end of the first switch is connected with the negative input end of the load;

the specific design process is as follows: determining the size of the receiving end one-way coil, namely the radius and the number of turns of the receiving end one-way coil according to the size of a charging target in practical application; determining the radius of a forward coil and a reverse coil of a transmitting terminal by an excitation source; determining the turn ratio between the forward coil and the backward coil of the transmitting terminal according to a mutual inductance formula, wherein the radius of the unidirectional coil of the receiving terminal is set as r_RThe number of turns is n_RSetting the radius of the forward coil of the forward and reverse series coils of the transmitting terminal as r_T ^fRadius of the reverse coil is r_T ^rAnd (3) according to a mutual inductance formula between two single-turn circular coils:

and (3) solving the mutual inductance between the forward and reverse series coils of the transmitting terminal and the unidirectional coil of the receiving terminal:

in the formula, mu₀Is a vacuum permeability of r₁And r₂The radii of the two single-turn round coils are respectively, d is the distance between the two single-turn round coils, and K (k) and E (k) are respectively the first type and the second type of elliptic integrals; n is_T ^fAnd n_T ^rNumber of turns, n, of the forward and reverse coils, respectively_RIs the number of turns r of the receiving end unidirectional coil_T ^fAnd r_T ^rRadius of the forward and reverse coils, r, respectively_RRadius of the receiving end unidirectional coil, D_ijThe distance between the ith turn of the forward coil or the reverse coil and the jth turn of the receiving end unidirectional coil is D, the distance between the center points of the forward coil or the reverse coil and the receiving end unidirectional coil is D, a is the radius of a lead, p is the pitch, and the pitch p of the close-wound coil is 0 and can be ignored;

by differentiating M (D) with respect to D, the formula:

determining the position D of a frequency split point when the forward coil is used alone as a transmitting coil_sChanging D to D₁＝D_sThe number of turns of the reverse coil can be obtained by substituting the equation;

changing the number of turns of the reverse coil according to a formula

Determining the mutual inductance curve between the transmitting end forward and backward series coil and the receiving end unidirectional coil to be changed along with the distanceThe flattening degree is changed, the smaller v is, the flatter the mutual inductance change curve is, wherein the number of turns of the transmitting end reverse coil corresponding to the flattest mutual inductance change curve between the transmitting end forward and reverse series coils and the receiving end unidirectional coil along with the transmission distance is selected as the optimal design number of turns, and in the formula, D is₀Is the initial distance between the forward and reverse series coils of the transmitting terminal and the unidirectional coil of the receiving terminal, D₁The distance between the two coils is the maximum value of mutual inductance between the transmitting end forward and reverse series coils and the receiving end unidirectional coil;

making a curve that the efficiency of the WPT/MRC system changes with the distance at the working frequency when the forward and reverse series coils are used as transmitting coils and a curve that the efficiency of the WPT/MRC system changes with the distance at the working frequency when the forward coil is used as the transmitting coil, and solving the problem that when the two curves are intersected, the transmission distance is D_m；

When the transmission distance is less than D_mWhen the WPT/MRC system with the forward and reverse series coils as the transmitting coils is used, the transmission efficiency of the WPT/MRC system with the forward and reverse series coils as the transmitting coils is higher than that of the WPT/MRC system with the forward coil as the transmitting coil, so that the forward and reverse series coils are used as the transmitting coils of the WPT/MRC system to inhibit frequency splitting and realize high-efficiency transmission of the system; when the transmission distance is greater than D_mWhen the system is used, the transmission efficiency of the WPT/MRC system with the forward and reverse series coils as the transmitting coils is lower than that of the WPT/MRC system with the forward coil as the transmitting coil, so that the reverse coil is short-circuited by closing the switch g, and the forward coil is used as the transmitting coil of the WPT/MRC system, so that the high-efficiency transmission of the system is kept;

then using an adjustable capacitor C₁And an adjustable capacitor C₂And tuning the transmitting end forward and reverse series coil and the receiving end unidirectional coil to the used working frequency to complete the design of the transmitting end forward and reverse series coil of the magnetic coupling resonance high-efficiency electric energy transmission coil for wireless electric energy transmission.

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