CN211296327U - Fractional order parallel electromagnetic field double-coupling wireless power transmission system - Google Patents

Fractional order parallel electromagnetic field double-coupling wireless power transmission system Download PDF

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CN211296327U
CN211296327U CN201922289399.0U CN201922289399U CN211296327U CN 211296327 U CN211296327 U CN 211296327U CN 201922289399 U CN201922289399 U CN 201922289399U CN 211296327 U CN211296327 U CN 211296327U
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fractional order
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parallel type
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end coupling
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张波
疏许健
江彦伟
魏芝浩
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South China University of Technology SCUT
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Abstract

The utility model discloses a fractional order parallel type electromagnetic field double coupling wireless electric energy transmission system, which comprises a high-frequency power current source, a fractional order parallel type transmitting circuit, a fractional order parallel type receiving circuit and a load; the fractional order parallel type transmitting circuit is composed of a primary side fractional order inductance coil, a first single-end coupling capacitance metal pole plate, a primary side fractional order compensation capacitance and a second single-end coupling capacitance metal pole plate which are connected in parallel, the fractional order parallel type receiving circuit is composed of a secondary side fractional order inductance coil, a third single-end coupling capacitance metal pole plate, a secondary side fractional order compensation capacitance and a fourth single-end coupling capacitance metal pole plate which are connected in parallel, and the first single-end coupling capacitance metal pole plate, the third single-end coupling capacitance metal pole plate, the second single-end coupling capacitance metal pole plate and the fourth single-end coupling capacitance metal pole plate are respectively matched into a pair of interactive coupling capacitance metal pole plates. The utility model discloses utilize fractional order component to realize parallelly connected type electric field coupling and the transmission of magnetic field coupling wireless power and transmit energy jointly, increase transmission distance and efficiency, can realize the constant voltage output.

Description

Fractional order parallel electromagnetic field double-coupling wireless power transmission system
Technical Field
The utility model belongs to the technical field of the transmission of space electric field coupling wireless power's technique and specifically relates to indicate a fractional order parallel type electromagnetic field double coupling wireless power transmission system.
Background
According to different power transmission implementation mechanisms and modes, wireless power transmission technologies can be broadly classified into magnetic field coupling type wireless power transmission technologies, electric field coupling type wireless power transmission technologies, and microwave type wireless power transmission technologies. The microwave type has a long transmission distance, but has a very low efficiency, low power and serious dissipation, and is applied less at present. In practical applications, magnetic field coupling type and electric field coupling type have been studied in recent years because of their high transmission power and high efficiency. However, the transmission performance of both of these two methods is severely limited by the transmission distance. With the increase of the distance, the transmission efficiency will be greatly reduced, which is not beneficial to the practical application of the system. At present, the transmission distance of electric field coupling type wireless power transmission is mostly on the order of centimeters, and the transmission distance of magnetic field coupling type wireless power transmission is mostly on the order of tens of centimeters. How to effectively increase the distance of wireless power transmission and maintain the high efficiency of the system is an important problem facing the technology at present.
At present, conventional space electric field coupling type and magnetic field coupling type wireless power transmission systems may be classified into a series-series type, a series-parallel type, a parallel-series type, and a parallel-parallel type according to connection modes of inductors and capacitors. The transmitting circuit adopts a series connection suitable for a voltage source type inverter as a power supply to supply electric energy, and the receiving circuit adopts a series connection suitable for a current source type inverter as a power supply to supply electric energy. The receiving circuit is connected in series and is suitable for the application occasions of high-power loads, such as electric automobiles and the like, while the receiving circuit is connected in parallel and is suitable for the application occasions of low-power loads, such as consumer electronics products, such as mobile phones and the like, and different connection modes have great research significance and practical application value.
The concept of fractional order elements (i.e., fractional order inductance and fractional order capacitance) is derived from fractional order calculus. In fact, the inductance and capacitance elements of integer order do not exist in nature, but the fractional order of the inductance and capacitance adopted at present is close to 1. With the continuous and deep knowledge of the inductance and capacitance characteristics, the fractional order influence of the inductance and capacitance characteristics is considered, or the fractional order of the inductance and capacitance characteristics is purposefully utilized to improve the circuit performance, and the fractional order characteristics have proved to be more advantageous than the integer order components in some application occasions, such as the application in impedance matching circuits. However, the conventional parallel electric field coupling type and magnetic field coupling type wireless power transmission systems are implemented based on integer-order elements, the degree of freedom of system parameter design is small, the resonant frequency is easily affected by load and distance, the system is easily detuned, the adjustable factors of output power and transmission efficiency are few, and the system is limited by a high-frequency current source technology and is difficult to further develop.
SUMMERY OF THE UTILITY MODEL
The utility model aims to overcome the defects of the prior art and provide a fractional order parallel type electromagnetic field double-coupling wireless power transmission system, which utilizes fractional order elements to realize the common transmission energy of the parallel type electric field coupling and the magnetic field coupling wireless power transmission, so that the coupling mechanisms generated by the two coupling modes are mutually overlapped, thereby not only greatly increasing the transmission distance and efficiency of the traditional parallel type electric field coupling and the parallel type magnetic field coupling wireless power transmission, but also increasing the dimensionality of parameter design, being easy for system optimization, realizing constant voltage output, effectively improving or even eliminating the influence of load and distance on the system resonant frequency, being beneficial to avoiding the occurrence of system detuning, reducing the system resonant frequency, reducing the current level requirement and design requirement of the system on a high-frequency current source, and having high transmission efficiency of low-power load, the wireless power transmission system is suitable for low-power application occasions, and the performance of the wireless power transmission system is completely different from that of a traditional integral-order parallel-parallel electric field coupling, magnetic field coupling and electromagnetic field double coupling wireless power transmission system.
In order to achieve the above object, the present invention provides a technical solution: a fractional order parallel type electromagnetic field double-coupling wireless power transmission system comprises a high-frequency power current source, a fractional order parallel type transmitting circuit, a fractional order parallel type receiving circuit and a load, wherein the high-frequency power current source is connected with the fractional order parallel type transmitting circuit and provides electric energy for the whole system, and the fractional order parallel type receiving circuit is connected with the load; the fractional order parallel type transmitting circuit consists of a primary fractional order inductance coil, a first single-end coupling capacitance metal pole plate, a primary fractional order compensation capacitance and a second single-end coupling capacitance metal pole plate which are connected in parallel, the fractional order parallel type receiving circuit consists of a secondary fractional order inductance coil, a third single-end coupling capacitance metal pole plate, a secondary fractional order compensation capacitance and a fourth single-end coupling capacitance metal pole plate which are connected in parallel, the first single-end coupling capacitance metal pole plate and the third single-end coupling capacitance metal pole plate are matched into a pair of interactive coupling capacitance metal pole plates, the second single-end coupling capacitance metal pole plate and the fourth single-end coupling capacitance metal pole plate are matched into another pair of interactive coupling capacitance metal pole plates, and the primary fractional order inductance coil and the secondary fractional order inductance coil are coupled and transmit electric energy through a magnetic field, meanwhile, displacement current is generated between each two pairs of coupling capacitor metal polar plates, electric energy is transmitted through electric field coupling, coupling mechanisms generated by the two coupling modes are mutually overlapped to wirelessly supply power to a load, and constant voltage output and system transmission power improvement can be realized by adjusting the order of a fractional order element.
Further, the differential relation between the voltage and the current of the primary side fractional order inductance coil and the secondary side fractional order inductance coil satisfies the following conditions:
Figure BDA0002322026140000031
the phase relation satisfies:
Figure BDA0002322026140000032
wherein iLnIs the current of a fractional order inductor uLnIs the voltage of a fractional order inductor, LβnIs the inductance value of the fractional order inductor,
Figure BDA0002322026140000033
is the phase of a fractional order inductor, βnIs the order of a fractional order inductor, and 0<βn2, where n-1 or 2 denotes a transmitting circuit or a receiving circuit, respectively.
Further, the differential relation between the voltage and the current of the primary side fractional order compensation capacitor and the secondary side fractional order compensation capacitor meets the following requirements:
Figure BDA0002322026140000034
the phase relation satisfies:
Figure BDA0002322026140000035
wherein iCnFor compensating the current of the capacitor in fractional order, uCnCompensating the voltage of the capacitor for fractional order, CαnIs the capacitance value of the fractional order compensation capacitor,
Figure BDA0002322026140000036
compensating the phase of the capacitor for fractional order, αnCompensating the order of the capacitance for fractional order, and 0<αn2, where n-1 or 2 denotes a transmitting circuit or a receiving circuit, respectively.
Furthermore, the capacitance values of the primary side fractional order compensation capacitor and the secondary side fractional order compensation capacitor are not only related to the load and the distance, but also related to the order of the fractional order element, and the influence of the load or distance change on the fractional order compensation capacitance value can be improved or even eliminated by adjusting the order of the fractional order element, so that the detuning of the system is improved or even avoided.
Further, the resonant frequency of the system depends on the order of the fractional order element, and the resonant frequency of the system can be reduced by adjusting the order of the fractional order element, so that the current level requirement and the design requirement of the system on the high-frequency current source are reduced.
Further, the smaller the power of the load, the higher the transmission efficiency thereof, i.e., a low-power load has a high transmission efficiency.
Further, when the order of the primary side fractional order inductance coil and the secondary side fractional order inductance coil is 1, the primary side fractional order inductance coil and the secondary side fractional order inductance coil are integer order inductance coils; when the order of the primary side fractional order compensation capacitor and the secondary side fractional order compensation capacitor is 1, the primary side fractional order compensation capacitor and the secondary side fractional order compensation capacitor are integer order capacitors.
Compared with the prior art, the utility model, have following advantage and beneficial effect:
1. meanwhile, two transmission modes of electric field coupling and magnetic field coupling are utilized to wirelessly supply power to the load, so that the transmission efficiency of the system is remarkably improved compared with that of the traditional electric field coupling and magnetic field coupling wireless power transmission system, the transmission distance is increased, and long-distance and stable wireless power transmission is realized.
2. The space electric field and magnetic field double-coupling wireless power transmission realized by adopting the fractional order element is completely different from the traditional electric field and magnetic field coupling wireless power transmission system, the freedom degree of parameter selection is increased, and the output power and the transmission efficiency are easy to adjust.
3. By selecting the order of the fractional order element, the influence of the distance on the fractional order compensation capacitance value can be effectively improved or even eliminated, and the detuning of the system can be avoided.
4. By adjusting the order of the fractional order element, the resonant frequency of the system can be greatly reduced, so that the requirements on a high-frequency power current source and a power electronic device are reduced, and the design of an actual system is facilitated.
5. By selecting the order of the proper fractional order element, the constant voltage output can be realized, and the wireless power supply of the constant voltage load is facilitated.
6. The smaller the power load, the higher the transmission efficiency, and the transmission power can be effectively improved by controlling the order of the fractional order element, which is beneficial to the application in the low-power occasions.
Drawings
Fig. 1 is a schematic diagram of a specific system structure provided in the embodiment.
Fig. 2 is an equivalent circuit schematic diagram of a specific system provided in the embodiment.
Detailed Description
To further illustrate the aspects and features of the present invention, the following detailed description of the embodiments of the present invention is provided in conjunction with the accompanying drawings, but the invention is not limited thereto.
As shown in fig. 1 and fig. 2, the fractional order parallel electromagnetic field double-coupling wireless power transmission system provided by this embodiment includes a high-frequency power current source IsFractional order parallel type transmitting circuit, fractional order parallel type receiving circuit and load RLSaid high-frequency power current source IsIs connected with a fractional order parallel type transmitting circuit to provide electric energy for the whole system, and the fractional order parallel type receiving circuit is connected with a load RLConnecting; the fractional order parallel type transmitting circuit is composed of a primary side fractional order inductance coil L connected in parallelβ1A first single-end coupling capacitor metal plate, a primary side fractional order compensation capacitor Cα1And a second single-end coupling capacitor metal polar plate, wherein the fractional order parallel receiving circuit comprises a secondary fractional order inductance coil L connected in parallelβ2A third single-end coupling capacitor metal polar plate, a secondary side fractional order compensation capacitor Cα2And a fourth single-end coupling capacitor metal plate, wherein the first single-end coupling capacitor metal plate and the third single-end coupling capacitor metal plate are matched into a pair of interactive coupling capacitor metal plates Cc1The second single-end coupling capacitor metal polar plate and the fourth single-end coupling capacitor metal polar plate are matched into another pair of interactive coupling capacitor metal polar plates Cc2The primary side fractional order inductance coil Lβ1And secondary fractional order inductance coil Lβ2The two pairs of coupling capacitor metal polar plates C transmit electric energy through magnetic field couplingc1、Cc2Displacement current is generated between the two, electric energy is transmitted through electric field coupling, and coupling mechanisms generated by the two coupling modes are mutually superposed to form a load RLAnd wireless power supply is carried out, and constant voltage output and system transmission power improvement can be realized by adjusting the order of the fractional order element.
Wherein, the order and inductance of the primary side fractional order inductance coil and the secondary side fractional order inductance coil are β respectively1、β2And Lβ1、Lβ2,β1、β2Satisfies 0<β1、2Less than or equal to 2; order of primary side fractional order compensation capacitor and secondary side fractional order compensation capacitorThe number and the capacity values are α respectively1、α2And Cα1、Cα2,α1、α2Satisfies 0<α1、2Less than or equal to 2. Impedance expressions of the primary side fractional order inductance coil, the primary side fractional order compensation capacitor, the secondary side fractional order inductance coil and the secondary side fractional order compensation capacitor are respectively as follows:
Figure BDA0002322026140000061
Figure BDA0002322026140000062
Figure BDA0002322026140000063
Figure BDA0002322026140000064
as can be seen from the above impedance expression, the fractional order inductance coil can be equivalent to a series connection of an integer order resistance and an integer order inductance which change with the operating frequency and the order, and the fractional order compensation capacitance can be equivalent to a series connection of an integer order resistance and an integer order capacitance which change with the operating frequency and the order, that is:
Figure BDA0002322026140000065
Figure BDA0002322026140000066
Figure BDA0002322026140000067
Figure BDA0002322026140000071
according to the coupled mode theory, the coupled mode equation of the system is as follows:
Figure BDA0002322026140000072
in the formula, a1And a2The energy storage method is characterized by comprising the following steps of (1) defining a complex variable stored by a primary side resonant circuit and a secondary side resonant circuit, wherein the square of a module value of the complex variable represents the energy stored by the resonant circuit, and the specific expression is as follows:
Figure BDA0002322026140000073
in the formula i1And i2Current of the transmitting circuit and current of the receiving circuit, u, respectivelyCα1_eqAnd uCα2_eqThe voltage of imaginary part impedance components of the primary side fractional order compensation capacitor and the secondary side fractional order compensation capacitor are respectively.
τ1、τ2Total loss rate of the transmitting circuit and total loss rate of the receiving circuit, and τ1=τCα1Lβ1,τ2=τCα2Lβ2LIn which τ isCα1、τLβ1、τCα2、τLβ2、τLRespectively the loss rate, tau, of each element in the circuitLFor the load factor, the specific expression is as follows:
Figure BDA0002322026140000074
Figure BDA0002322026140000075
Figure BDA0002322026140000081
Figure BDA0002322026140000082
the load factor is:
Figure BDA0002322026140000083
ω1、ω2the resonant angular frequencies of the transmitter and receiver, respectively, are expressed as follows:
Figure BDA0002322026140000084
from the above formula, the resonance angular frequency of the system depends not only on the inductance value of the fractional order inductance coil and the capacitance value of the fractional order compensation capacitor, but also on the orders of the fractional order inductance coil and the fractional order compensation capacitor, whereas the resonance angular frequency of the conventional integer order electric field and magnetic field coupling wireless power transmission system is determined only by the inductance value and the capacitance value.
Figure BDA0002322026140000085
Is the electromagnetic field energy coupling coefficient, where kcIs the electric field coupling coefficient, kmFor the mutual inductance coupling coefficient, the specific expression is as follows:
Figure BDA0002322026140000086
Figure BDA0002322026140000087
here, the first and second liquid crystal display panels are,
Figure BDA0002322026140000091
Cc1and Cc2Is an equivalent capacitance of a single pair of coupled metal plates, generally having Cc1≈Cc2S is the area of the plate, d is the transmission distance, and kc、km<<1。
FejωtFor applying an excitation to an expression in the coupled-mode equation, an
Figure BDA0002322026140000092
IsIs outsideAn effective value of the high frequency power current source.
A can be obtained according to a coupled mode equation1And a2The steady state solution of (c) is:
Figure BDA0002322026140000093
the energy | a of the transmitting circuit and the receiving circuit1|2、|a2|2Respectively as follows:
Figure BDA0002322026140000094
the output power and transmission efficiency of the system thus obtained are:
Figure BDA0002322026140000095
Figure BDA0002322026140000096
in order to make the system transmitting circuit and receiving circuit implement resonance compensation of the system, the working angular frequency satisfies: omega-omega1=ω2The output power and transmission efficiency of the system can then be expressed as:
Figure BDA0002322026140000097
Figure BDA0002322026140000101
from the above equation, the output power and transmission efficiency of the system not only depend on the working angular frequency ω of the power supply and the coupling capacitance CcDependent on the mutual inductance M, and also on the order β of the fractional-order inductor1、β2And fractional order compensation capacitor α1、α2Is related to the order of (a). The output power and the transmission efficiency of the traditional electromagnetic field double-coupling wireless power transmission system are only equal to the working angular frequencyRatio omega, coupling capacitance value CcAnd the mutual inductance M.
According to the above analysis, the utility model discloses utilize fractional order component to realize the common transmission energy of parallelly connected type electric field coupling and magnetic field coupling wireless power transmission, make the coupling mechanism that two kinds of coupling modes produced superpose each other, not only greatly increased transmission distance and the efficiency of traditional parallelly connected type electric field coupling and parallelly connected type magnetic field coupling wireless power transmission, the dimensionality of parameter design has still been increased, easily system optimization, and can realize constant voltage output, effectively improve and even eliminate the influence of load and distance to system resonance frequency, thereby be favorable to avoiding the emergence of system detuning, and can reduce system resonance frequency, thereby reduce system's current level requirement and the design requirement to high frequency current source, the low-power load has high transmission efficiency, be applicable to the application occasion of low power, the performance also distinguishes in traditional integer order parallelly connected-parallelly connected type electric field coupling completely, Magnetic field coupling and electromagnetic field double coupling's wireless power transmission system, the utility model discloses the advantage of system is obvious, is worth promoting.
The above embodiments are preferred embodiments of the present invention, but the embodiments of the present invention are not limited by the above embodiments, and any other changes, modifications, substitutions, combinations, and simplifications which do not depart from the spirit and principle of the present invention should be equivalent replacement modes, and all are included in the scope of the present invention.

Claims (3)

1. A fractional order parallel type electromagnetic field double-coupling wireless power transmission system is characterized in that: the system comprises a high frequency power current source (I)s) Fractional order parallel type transmitting circuit, fractional order parallel type receiving circuit and load (R)L) Said high-frequency power current source (I)s) Connected with a fractional order parallel type transmitting circuit for supplying power to the whole system, and a load (R)L) Connecting; the fractional order parallel type transmitting circuit comprises a primary side fractional order inductance coil (L) connected in parallelβ1) A first single-end coupling capacitor metal plate, a primary side fractional order compensation capacitor (C)α1) And a second single-end coupling capacitor metal plate, wherein the fractional order parallel receiving circuit comprises a secondary fractional order inductance coil (L) connected in parallelβ2) A third single-end coupling capacitor metal polar plate, a secondary side fractional order compensation capacitor (C)α2) And a fourth single-ended coupling capacitor metal plate, wherein the first single-ended coupling capacitor metal plate and the third single-ended coupling capacitor metal plate are matched into a pair of interacting coupling capacitor metal plates (C)c1) The second single-end coupling capacitor metal polar plate and the fourth single-end coupling capacitor metal polar plate are matched into another pair of interactive coupling capacitor metal polar plates (C)c2) Said primary side fractional order inductor (L)β1) And a secondary fractional order inductor (L)β2) The two pairs of coupling capacitance metal polar plates (C) transmit electric energy through magnetic field couplingc1、Cc2) Displacement current is generated between the two, electric energy is transmitted through electric field coupling, and coupling mechanisms generated by the two coupling modes are mutually superposed to form a load (R)L) And wireless power supply is carried out, and constant voltage output and system transmission power improvement can be realized by adjusting the order of the fractional order element.
2. The fractional order parallel type electromagnetic field double coupling wireless power transmission system according to claim 1, characterized in that: the primary side fractional order inductor (L)β1) And a secondary fractional order inductor (L)β2) The voltage and current differential relation satisfies:
Figure FDA0002322026130000011
the phase relation satisfies:
Figure FDA0002322026130000012
wherein iLnIs the current of a fractional order inductor uLnIs the voltage of a fractional order inductor, LβnIs the inductance value of the fractional order inductor,
Figure FDA0002322026130000013
being phases of fractional order induction coilsBit, βnIs the order of a fractional order inductor, and 0<βn2, where n-1 or 2 denotes a transmitting circuit or a receiving circuit, respectively.
3. The fractional order parallel type electromagnetic field double coupling wireless power transmission system according to claim 1, characterized in that: the primary side fractional order compensation capacitor (C)α1) And secondary side fractional order compensation capacitance (C)α2) The voltage and current differential relation satisfies:
Figure FDA0002322026130000021
the phase relation satisfies:
Figure FDA0002322026130000022
wherein iCnFor compensating the current of the capacitor in fractional order, uCnCompensating the voltage of the capacitor for fractional order, CαnIs the capacitance value of the fractional order compensation capacitor,
Figure FDA0002322026130000023
compensating the phase of the capacitor for fractional order, αnCompensating the order of the capacitance for fractional order, and 0<αn2, where n-1 or 2 denotes a transmitting circuit or a receiving circuit, respectively.
CN201922289399.0U 2019-12-17 2019-12-17 Fractional order parallel electromagnetic field double-coupling wireless power transmission system Withdrawn - After Issue CN211296327U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN110971007A (en) * 2019-12-17 2020-04-07 华南理工大学 Fractional order parallel electromagnetic field double-coupling wireless power transmission system

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN110971007A (en) * 2019-12-17 2020-04-07 华南理工大学 Fractional order parallel electromagnetic field double-coupling wireless power transmission system
CN110971007B (en) * 2019-12-17 2024-06-04 华南理工大学 Fractional order parallel electromagnetic field double-coupling wireless power transmission system

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