CN103915912B - A kind of fractional order parallel-serial resonant radio energy transmission system - Google Patents

Abstract

The invention provides a kind of fractional order parallel-serial resonant radio energy transmission system, comprise high frequency power source, radiating portion, receiving unit and load, radiating portion comprises the former limit fractional order electric capacity and former limit fractional order inductance that are connected in parallel, and former limit fractional order inductance has former limit resistance; Receiving unit comprises the secondary fractional order electric capacity and secondary fractional order inductance that are connected in series, and secondary fractional order inductance has secondary resistance.The present invention adopts fractional order element to realize wireless power transmission, adds the dimension of parameter designing, is different from the radio energy transmission system that traditional integer rank element realizes completely.

Description

A kind of fractional order parallel-serial resonant radio energy transmission system

Technical field

The invention belongs to the field of wireless power transmission or wireless power transmission technology, particularly a kind of fractional order parallel-serial resonant radio energy transmission system.

Background technology

Wireless power transmission or wireless power transmission technology were just attempted experimentally by American inventor tesla (NicolaTesla) before more than 100 years.2006, the researcher of the Massachusetts Institute of Technology (MIT) utilizes the resonance technique of physics successfully to light the bulb of a 60W with the efficiency of 40% in 2m distance left and right, this experiment is not only the reproduction of tesla's experiment, another new breakthrough of wireless power transmission technology especially, and started the upsurge of wireless power transmission research.

Wireless power transmission technology is a kind of delivery of electrical energy mode of wide application prospect, there is the advantages such as safe, reliable, flexible, convenient, day by day be subject to the attention of countries in the world, and be more and more widely used in the various place being not suitable for or being inconvenient to use conductive contact electric energy transmitting, as implantable medical device, mobile electronic product, robot, rail electric car such as to be powered at the occasion, and be expected in small-power electronic product wireless charging, to replace traditional plug charging in the near future.

Current radio energy transmission system all realizes based on integer rank inductance, electric capacity, and its resonance frequency is only determined by inductance value and capacitance, and therefore, its system only need consider parameter value, and without the need to considering the exponent number of element, the degree of freedom of design is fewer.Meanwhile, the element of real system is fractional order in essence, but the most exponent number in current reality is close to 1, and the situation for fractional order is ignored completely.Traditional designs radio energy transmission system by the modeling on integer rank, and under certain conditions, theoretical and actual error may be very large.

The generation deriving from fractional calculus of fractional order device (as fractional order electric capacity and fractional order inductance) concept, and the concept of fractional calculus has had the history of more than 300 year, is almost born with integer rank calculus simultaneously.But due to fractional order more complicated, and never have good numerical analysis tools, therefore it is in the theory analysis stage always.In recent decades, due to the development of biotechnology, macromolecular material etc., it is found that integer rank calculus well can not explain the phenomenon that nature exists, therefore fractional calculus starts to be paid attention to, and start to be applied to engineering field, its investigation and application at control field is day by day perfect.Meanwhile, the fractional order device at two ends is out manufactured in laboratory.But fractional order circuit and some special character of system are studied, and are not mentioned especially in the application in wireless power transmission field.

In view of current fractional order element or fractional order circuit huge advantage in some aspects, and it is not also applied to wireless power transmission field, is therefore necessary to propose a kind of fractional order parallel-serial resonance wireless points electric energy transmission system.

Summary of the invention

The object of the invention is to overcome above-mentioned the deficiencies in the prior art, a kind of fractional order parallel-serial resonant radio energy transmission system is provided.

The present invention is achieved through the following technical solutions:

A kind of fractional order parallel-serial resonant radio energy transmission system, comprise high frequency power source, radiating portion, receiving unit and load, radiating portion comprises the former limit fractional order electric capacity and former limit fractional order inductance that are connected in parallel, former limit fractional order inductance there is former limit resistance; Receiving unit comprises the secondary fractional order electric capacity and secondary fractional order inductance that are connected in series, and secondary fractional order inductance has secondary resistance.

Described a kind of fractional order parallel-serial resonant radio energy transmission system, former limit fractional order electric capacity, the voltage of secondary fractional order electric capacity, current differential relation are all satisfied: phase relation meets: wherein, i _cfor fractional order capacitance current, v _cfor fractional order capacitance voltage, α is the exponent number of fractional order electric capacity, and 0 < α≤2, C ^αfor the value of fractional order electric capacity.

Described a kind of fractional order parallel-serial resonant radio energy transmission system, former limit fractional order inductance secondary fractional order inductance voltage, current differential relation all satisfied: phase relation meets: wherein, v _lfor the voltage of fractional order inductance, i _lfor the electric current of fractional order inductance, β is the exponent number of fractional order inductance, and 0 < β≤2, L ^βfor the value of fractional order inductance.

In described a kind of fractional order parallel-serial resonant radio energy transmission system, be the wireless power transmission realized by the mode of fractional order parallel-serial resonance coupling between radiating portion and receiving unit.

Operation principle of the present invention is: radiating portion and receiving unit are respectively by former limit fractional order electric capacity former limit fractional order inductance former limit resistance R _p, secondary fractional order electric capacity secondary fractional order inductance secondary resistance R _sform fractional order RLC parallel-serial resonant circuit, radiating portion and receiving unit realize the wireless transmission of electric energy by the mode that resonance is coupled.

Compared with prior art, tool of the present invention has the following advantages:

1, the wireless power transmission adopting fractional order element to realize, is different from radio energy transmission system in the past completely, adds the degree of freedom of Selecting parameter.

2, by the exponent number of selection element, greatly can reduce the resonance frequency of radio energy transmission system, thus reduce the requirement to power electronic device, be very beneficial for the design of real system.

3, by selecting suitable fractional order exponent number, through-put power can be made larger.

Accompanying drawing explanation

Fig. 1 is the schematic diagram of fractional order parallel-serial resonant radio energy transmission system of the present invention.

Fig. 2 is α=1.2, power output during β=0.9 and the relation curve of frequency f.

Fig. 3 is α=0.8, efficiency of transmission during β=0.9 and the relation curve of frequency f.

Fig. 4 is α=1.2, power output during β=1.5 and the relation curve of frequency f.

Fig. 5 is α=0.8, power output during β=1.5 and the relation curve of frequency f.

Specific embodiments

Be further described below in conjunction with the concrete enforcement of accompanying drawing to invention, but enforcement of the present invention and protection are not limited thereto.

Embodiment

As shown in Figure 1, be the schematic diagram of fractional order parallel-serial resonant radio energy transmission system of the present invention, below in conjunction with this figure, operation principle of the present invention be described.In Fig. 1, high frequency power source I _s, former limit fractional order electric capacity former limit fractional order inductance with former limit resistance R _pconnect and compose parallel resonance; Secondary fractional order electric capacity secondary fractional order inductance secondary resistance R _swith load R _lconnect and compose series resonance successively; Radiating portion and receiving unit realize wireless power transmission by mutual inductance M.In order to the convenience analyzed, make former limit fractional order electric capacity with secondary fractional order electric capacity parameter is consistent, and omits upper and lower mark, is designated as C; Make former limit fractional order inductance with secondary fractional order inductance parameter is consistent, and omits upper and lower mark, is designated as L; Make former limit resistance R _pwith secondary resistance R _sfor R.Then can obtain the Fractional Differential Equation of system:

$i_s=C\frac{d^{\mathrm{\&alpha;}}{v}_{C1}}{{\mathrm{dt}}^{\mathrm{\&alpha;}}}+i_1$

$v_{C1}=L\frac{d^{\mathrm{\&beta;}}{i}_1}{{\mathrm{dt}}^{\mathrm{\&beta;}}}+M\frac{d^{\mathrm{\&beta;}}{i}_2}{{\mathrm{dt}}^{\mathrm{\&beta;}}}+i_{1}R$

$i_2=C\frac{d^{\mathrm{\&alpha;}}{v}_{c2}}{{\mathrm{dt}}^{\mathrm{\&alpha;}}}$

$0=L\frac{d^{\mathrm{\&beta;}}{i}_2}{{\mathrm{dt}}^{\mathrm{\&beta;}}}+M\frac{d^{\mathrm{\&beta;}}{i}_1}{{\mathrm{dt}}^{\mathrm{\&beta;}}}+i_{2}R+v_{C2}+i_2{R}_L$

In formula, i _sfor the transient expression form of high frequency power source, i ₁for former limit fractional order inductive current, i ₂for secondary fractional order inductive current, v _c1for former limit fractional order capacitance voltage, v _c2for secondary fractional order capacitance voltage.The differential equation of said system can be obtained by Laplace transform:

I _S(s)＝s ^αCV _C1(s)+I ₁(s)

V _C1(s)＝s ^βLI ₁(s)+s ^βMI ₂(s)+I ₁(s)R

I ₂(s)＝s ^αCV _C2(s)

0＝s ^βLI ₂(s)+s ^βMI ₁(s)+I ₂(s)R+V _C2(s)+I ₂(s)R _L

Symbol in above equation group is Laplace transform form, has one-to-one relationship, i.e. I with the differential equation of system ₁for former limit fractional order inductive current, I ₂for secondary fractional order inductive current, V _c1for former limit fractional order capacitance voltage, V _c2for secondary fractional order capacitance voltage.Solve:

$I_2\left(s\right)=\frac{s^{\mathrm{\&alpha;}+\mathrm{\&beta;}}{\mathrm{MCI}}_S\left(s\right)}{s^{2(\mathrm{\&alpha;}+\mathrm{\&beta;})}{M}^2{C}^2-[1+s^{\mathrm{\&alpha;}}(R+R_L)C+s^{\mathrm{\&alpha;}+\mathrm{\&beta;}}\mathrm{LC}](1+s^{\mathrm{\&alpha;}+\mathrm{\&beta;}}\mathrm{LC}+s^{\mathrm{\&alpha;}}\mathrm{RC})}$

In a frequency domain, s=j ω is had.Then can in the hope of power output P _ofor:

$P_o=I_2^2{R}_L$

From the expression formula of power output, mainly α and β is relevant with mutual inductance M, operating angle frequencies omega, fractional order exponent number for the size of power output.Analyze further below, operating frequency is on the impact of power output, and other parameters remain unchanged.Situation of below dividing discusses fractional order exponent number to the impact of systematic function:

1) as α >1, β <1, as an example, a kind of design parameter of fractional order parallel-serial resonant radio energy transmission system is: I _s=1A, L=100 μ H, C=0.2533nF, R _l=5 Ω, coupling coefficient k=0.1(and mutual inductance M=k × L), α=1.2, β=0.9, R=0.5 Ω.Then the relation curve of power output and frequency f as shown in Figure 2.System resonance frequency of (i.e. α=1, β=1, other parameter constants) under same parameter in integer rank is 1MHz, and as shown in Figure 2, the resonance frequency of system is less than 1MHz.As can be seen here, the resonance frequency of fractional order circuit parallel resonance radio energy transmission system can be reduced by choosing fractional order exponent number, thus be conducive to the design of radio energy transmission system.

2) as α <1, β <1, as an example, a kind of design parameter of fractional order parallel-serial resonant radio energy transmission system is: I _s=1A, L=100 μ H, C=0.2533nF, R _l=5 Ω, coupling coefficient k=0.1(and mutual inductance M=k × L), α=0.8, β=0.9, R=0.5 Ω.Then the relation curve of power output and frequency f as shown in Figure 3, and this situation can improve the resonance frequency of system greatly, do not wish to occur this situation in real system.

3) as α >1, β >1, as an example, a kind of design parameter of fractional order parallel-serial resonant radio energy transmission system is: I _s=1A, L=100 μ H, C=0.2533nF, R _l=5 Ω, coupling coefficient k=0.1(and mutual inductance M=k × L), α=1.2, β=1.5, R=0.5 Ω.Then the relation curve of power output and frequency f as shown in Figure 4.Although this situation reduces the resonance frequency of system, power output is unsatisfactory, therefore also should avoid during design.

4) as α <1, β >1, as an example, a kind of design parameter of fractional order parallel-serial resonant radio energy transmission system is: I _s=1A, L=100 μ H, C=0.2533nF, R _l=5 Ω, coupling coefficient k=0.1(and mutual inductance M=k × L), α=0.8, β=1.5, R=0.5 Ω.Then the relation curve of power output and frequency f as shown in Figure 4.Although this situation reduces the resonance frequency of system, power output is unsatisfactory, therefore also should avoid during design.

Situation described above is applicable equally for the situation of α=β.

Above-described embodiment is the present invention's preferably execution mode; but embodiments of the present invention are not limited by the examples; change, the modification done under other any does not deviate from Spirit Essence of the present invention and principle, substitute, combine, simplify; all should be the substitute mode of equivalence, be included within protection scope of the present invention.

Claims (1)

1. a fractional order parallel-serial resonant radio energy transmission system, comprises high frequency power source (I _s), radiating portion, receiving unit and load (R _l), it is characterized in that radiating portion comprises the former limit fractional order electric capacity be connected in parallel with former limit fractional order inductance former limit fractional order inductance there is former limit resistance (R _p); Receiving unit comprises the secondary fractional order electric capacity be connected in series with secondary fractional order inductance secondary fractional order inductance there is secondary resistance (R _s); Former limit fractional order electric capacity secondary fractional order electric capacity voltage, current differential relation all satisfied: phase relation meets: wherein, i _cfor fractional order capacitance current, v _cfor fractional order capacitance voltage, α is the exponent number of fractional order electric capacity, and 0 < α≤2, C ^αfor the value of fractional order electric capacity; Former limit fractional order inductance secondary fractional order inductance voltage, current differential relation all satisfied: phase relation meets: wherein, v _lfor the voltage of fractional order inductance, i _lfor the electric current of fractional order inductance, β is the exponent number of fractional order inductance, and 0 < β≤2, L ^βfor the value of fractional order inductance.