CN107733096B - Parallel-serial wireless power transmission system based on negative resistance - Google Patents

Abstract

The invention discloses a parallel-serial wireless power transmission system based on negative resistance, which comprises a negative resistance and a transmitting circuit which are connected, and a receiving circuit and a load which are connected; the transmitting circuit comprises a primary capacitor and a primary transmitting coil which are connected in parallel, the primary transmitting coil comprises a primary inductor and a transmitting circuit internal resistance which are connected in series, and the transmitting circuit internal resistance refers to all positive resistors of the transmitting circuit except for a resistor of which the secondary side is reflected to the primary side; the receiving circuit comprises a secondary receiving coil and a secondary capacitor which are connected in series, the secondary receiving coil comprises a secondary inductor and a receiving circuit internal resistance which are connected in series, and the receiving circuit internal resistance refers to all positive resistances of the receiving circuit except a load. The invention utilizes the property of negative resistance to generate energy to realize the energy supply to the circuit, thereby replacing a high-frequency inversion source in the traditional parallel-serial wireless power transmission system, leading the structure of the system to be simpler, leading the working frequency to be higher and leading the transmission efficiency to be more stable.

Description

Parallel-serial wireless power transmission system based on negative resistance

Technical Field

The invention relates to the field of wireless power transmission or wireless power transmission technology, in particular to a parallel-serial wireless power transmission system based on negative resistance.

Background

The wireless power transmission technology can realize complete electrical isolation between the power supply and the electric equipment, and has the advantages of safety, reliability and flexibility. As early as the end of the 19 th century, nikola Tesla (Nikola Tesla) utilized the principle of wireless power transfer to illuminate a bulb without any wire connection. Wireless power transmission based on magnetic coupling resonance is a breakthrough progress made by students in the field of wireless power transmission by MIT, and since 2007 is published, very great reverberation is caused in the field of wireless power transmission, more and more students are added to basic research and application development of wireless power transmission technology.

In the current resonant wireless power transmission system, the realization of a high-frequency, high-reliability and high-power supply is always an important difficult problem of applying the technology to the transmission of high-power loads. Conventional wireless power transmission systems are generally composed of a driving source, a transmitting circuit, a receiving circuit, and a load, wherein the driving source determines system parameters and is the most important part in wireless power transmission as a converting and controlling part of a system power supply. In order to meet the development trend of high frequency and high efficiency of the wireless power transmission system, a switch type driving source (power amplifier) such as a class-D power amplifier and a class-E power amplifier is generally adopted, and the theoretical efficiency of the class-D power amplifier reaches 100%, but the output power is lower, so that the power amplifier is only suitable for low-power application occasions. At present, bridge type inverters formed by IGBT and MOSFET are mostly adopted in high-power application occasions, and meanwhile, wireless transmission of electric energy is realized by matching different soft switching algorithms, but the working frequency is low, and the transmission distance is short. Therefore, under the existing technical conditions, it is quite difficult to realize a high-frequency (MHz or more), high-reliability and high-power switching converter due to the restriction of factors such as power switching transistors and circuit topology structures.

Negative resistance is an active component that satisfies ohm's law and the series-parallel rule. In contrast to the resistor, the phase difference between the voltage and the current fundamental wave of the negative resistance is pi, and the power in the circuit is negative, namely, the electric energy is released to the circuit. Negative resistance has a variety of implementations, such as being constructed with positive resistance and op-amps. In the past, negative resistance has been used to raise the input impedance of an inverting amplifier, neutralize the positive resistance of an LC tank, etc., and have rarely been used as a power source to power a circuit. Compared with a high-frequency inverter, the negative resistance has the advantages of simple system structure, no need of using MOSFET, high working frequency and the like, so that the problem that the conventional high-frequency inverter cannot be further increased in frequency can be solved. And the operating frequency of the system is determined by the values of the components in the circuit. At an operating frequency, the transmission efficiency of the system can be maintained at a very high level and remains substantially constant over a long range with distance changes, achieving stable transmission of radio energy.

Disclosure of Invention

The invention aims to overcome the defects of the prior art, and provides a parallel-serial wireless power transmission system based on negative resistance, which utilizes the property of energy generated by negative resistance to realize the energy supply to a circuit, thereby replacing a high-frequency inversion source in the traditional parallel-serial wireless power transmission system, and leading the system to have simpler structure, higher working frequency and more stable transmission efficiency.

In order to achieve the above purpose, the technical scheme provided by the invention is as follows: the parallel-serial wireless power transmission system based on the negative resistance comprises a negative resistance, a transmitting circuit, a receiving circuit and a load, wherein the negative resistance and the transmitting circuit are connected, and the receiving circuit and the load are connected; the transmitting circuit comprises a primary capacitor and a primary transmitting coil which are connected in parallel, the primary transmitting coil comprises a primary inductor and a transmitting circuit internal resistance which are connected in series, and the transmitting circuit internal resistance refers to all positive resistors of the transmitting circuit except for a resistor of a secondary side reflected to the primary side; the receiving circuit comprises a secondary receiving coil and a secondary capacitor which are connected in series, wherein the secondary receiving coil comprises a secondary inductor and a receiving circuit internal resistance which are connected in series, and the receiving circuit internal resistance refers to all positive resistances of the receiving circuit except a load.

The voltage and current relationship of the negative resistance satisfies the following conditions: v_R＝-Ri_R, the phase relationship satisfies: Wherein i_R is a current fundamental wave flowing through a negative resistance, v_R is a voltage fundamental wave at two ends of the negative resistance, R is a resistance value of the negative resistance,/>Is the phase difference between v_R and i_R; the power of the negative resistance satisfies: /(I)P is the power of the negative resistance, -indicating that the negative resistance discharges energy outwards.

Compared with the prior art, the invention has the following advantages and beneficial effects:

1. the system has simple structure and various negative resistance construction modes.

2. The negative resistance is utilized to replace a high-frequency power source of the parallel-serial wireless power transmission system, so that the technical problem that the current high-frequency and high-power switch converter is difficult to realize can be effectively solved.

3. The system operating frequency is determined by the component values in the circuit. At the working frequency, the system can keep high efficiency, and stable wireless power transmission is realized.

Drawings

Fig. 1 is a circuit diagram of a system provided in an embodiment.

Fig. 2 is a waveform diagram of the voltage and current of the negative resistance in the embodiment.

Fig. 3 is a graph showing a relationship between transmission efficiency and transmission distance in the embodiment.

Detailed Description

The invention will be further illustrated with reference to specific examples.

The basic principle of the parallel-serial wireless power transmission system based on the negative resistance provided by the embodiment is that the negative resistance is utilized to release energy and provide electric energy outwards, so that the parallel-serial wireless power transmission system is used for replacing a high-frequency power source in the traditional parallel-serial wireless power transmission system, and the technical problem that the conventional high-frequency and high-power switch converter is difficult to realize is effectively solved.

As shown in fig. 1, the implementation circuit of the system comprises a negative resistance-R and a transmitting circuit which are connected, and a receiving circuit and a load R_L which are connected, wherein the transmitting circuit and the receiving circuit realize wireless transmission of electric energy in an electromagnetic induction coupling mode; the transmitting circuit comprises a primary capacitor C₁ and a primary transmitting coil which are connected in parallel, the primary transmitting coil comprises a primary inductor L₁ and a transmitting circuit internal resistance R_S1 which are connected in series, and the transmitting circuit internal resistance R_S1 refers to all positive resistors of the transmitting circuit except for a resistor of a secondary side reflected to a primary side; the receiving circuit comprises a secondary receiving coil and a secondary capacitor C₂ which are connected in series, the secondary receiving coil comprises a secondary inductor L₂ and a receiving circuit internal resistance R_S2 which are connected in series, and the receiving circuit internal resistance R_S2 refers to all positive resistances of the receiving circuit except a load.

For convenient analysis, the parameters of the internal resistance R_S1 of the transmitting circuit and the internal resistance R_S2 of the receiving circuit are consistent and are R_S; the parameters of the primary side capacitor C₁ and the secondary side capacitor C₂ are consistent and are C; and the primary inductance L₁ and the secondary inductance L₂ are consistent in parameters and are L.

The coupling mode of the system is as follows:

In the method, in the process of the invention,For the natural frequency of the transmitting coil and the receiving coil,/>For the internal resistance loss coefficient of the transmitting circuit and the receiving circuit,/>Is a negative resistance gain coefficient,/>Is the inverse of the negative resistance,/>For the load factor,/>For the coupling coefficient between the transmitting circuit and the receiving circuit,/>And M is the mutual inductance between the primary side inductance and the secondary side inductance, and is the mutual inductance coupling coefficient between the transmitting coil and the receiving coil.

The eigenfrequencies of the system available are:

when gamma₁＝2τ₀+τ_L is reached, the electric energy provided to the circuit by the negative resistance connected with the transmitting circuit is completely absorbed by the internal resistance of the transmitting circuit, the internal resistance of the receiving circuit and the load.

Assuming that the initial energy of the system is stored in pattern a₁, let a₁(0)＝1,a₂ (0) =0, the expression of patterns a₁ and a₂ is:

Then:

the transmission efficiency of the system is as follows:

As can be seen from the above equation, if the electric energy provided by the negative resistance is absorbed by the internal resistance of the transmitting circuit, the internal resistance of the receiving circuit and the load, namely gamma₁＝2τ₀+τ_L, when the system works in the region where kappa is equal to or greater than tau₀+τ_L, the working frequency isTransmission efficiency maintenance/>When the system works in the region of kappa < tau₀+τ_L, the working frequency is omega=omega₀, and the transmission efficiency is changed along with the coupling coefficient between the transmitting circuit and the receiving circuit, which is that

Let natural frequency of transmitting coil and receiving coil be f₀ =2 MHz, primary side inductance and secondary side inductance be L=10μh, primary side electric capacity and secondary side electric capacity be C=0.633 nF, transmitting circuit internal resistance and receiving circuit internal resistance be R_S =0.5Ω, load resistance be R_L =10Ω.

The voltage fundamental wave and current fundamental wave relation of the negative resistance meets the following conditions: v_R＝-Ri_R, the phase relationship satisfies: output power is satisfied/>Taking the mutual inductance coupling coefficient k=0.3 as an example, fig. 2 shows that the phase difference between the voltage fundamental wave and the current fundamental wave of the negative resistance is pi, that is, the electric energy is released outwards.

The relationship between the transmission efficiency and the transmission distance of the system obtained by the equation (6) is shown as a solid line in fig. 3, and the solid points are the transmission efficiencies at different transmission distances obtained by the PSIM circuit simulation, so that the theoretical analysis and the simulation result are consistent. Under the condition that the electric energy provided by negative resistance is completely absorbed by the internal resistance of the transmitting circuit, the internal resistance of the receiving circuit and the load, namely under the condition of gamma₁＝2τ₀+τ_L, when the system works in the region with the kappa being more than or equal to tau₀+τ_L, the transmission efficiency is keptConstant, when the system works in the region of kappa < tau₀+τ_L, the transmission efficiency changes along with the coupling coefficient between the transmitting circuit and the receiving circuit, which is that

According to the analysis, the parallel-serial wireless electric energy transmission system based on the negative resistance has the property of releasing power, provides electric energy for a circuit, effectively replaces the function of a high-frequency power source, ensures that the system is simpler in structure, keeps the transmission efficiency basically constant within a certain range, is beneficial to application in more occasions, and is obvious in advantage and worth popularizing.

The above embodiments are only preferred embodiments of the present invention, and are not intended to limit the scope of the present invention, so variations in shape and principles of the present invention should be covered.

Claims (1)

1. The parallel-serial wireless power transmission system based on negative resistance is characterized in that: the device comprises a negative resistor, a transmitting circuit, a receiving circuit and a load, wherein the negative resistor and the transmitting circuit are connected, and the receiving circuit and the load are connected; the transmitting circuit comprises a primary capacitor and a primary transmitting coil which are connected in parallel, the primary transmitting coil comprises a primary inductor and a transmitting circuit internal resistance which are connected in series, and the transmitting circuit internal resistance refers to all positive resistors of the transmitting circuit except for a resistor of a secondary side reflected to the primary side; the receiving circuit comprises a secondary receiving coil and a secondary capacitor which are connected in series, wherein the secondary receiving coil comprises a secondary inductor and a receiving circuit internal resistance which are connected in series, and the receiving circuit internal resistance refers to all positive resistances of the receiving circuit except a load;

The voltage and current relationship of the negative resistance satisfies the following conditions: v_R＝-Ri_R, the phase relationship satisfies: Wherein i_R is a current fundamental wave flowing through a negative resistance, v_R is a voltage fundamental wave at two ends of the negative resistance, R is a resistance value of the negative resistance,/>Is the phase difference between v_R and i_R; the power of the negative resistance satisfies: /(I)P is the power of the negative resistance, -indicating that the negative resistance is discharging energy outwards;

The parameters of the internal resistance R_S1 of the transmitting circuit and the internal resistance R_S2 of the receiving circuit are consistent and are R_S; the parameters of the primary side capacitor C₁ and the secondary side capacitor C₂ are consistent and are C; the primary inductance L₁ and the secondary inductance L₂ are consistent in parameters and are L;

the eigenfrequency of the system is:

In the method, in the process of the invention,For the natural frequency of the transmitting coil and the receiving coil,/>For the internal resistance loss coefficient of the transmitting circuit and the receiving circuit,/>Is a negative resistance gain coefficient,/>Is the inverse of the negative resistance,/>For the load R_L coefficient of the load,For the coupling coefficient between the transmitting circuit and the receiving circuit,/>M is the mutual inductance between the primary side inductance and the secondary side inductance, which is the mutual inductance coupling coefficient between the transmitting coil and the receiving coil;

If the electric energy provided by the negative resistance is completely absorbed by the internal resistance of the transmitting circuit, the internal resistance of the receiving circuit and the load, namely gamma₁＝2τ₀+τ_L, when the system works in the region with kappa being more than or equal to tau₀+τ_L, the working frequency is thatTransmission efficiency maintenanceWhen the system works in the region of kappa < tau₀+τ_L, the working frequency is omega=omega₀, the transmission efficiency changes along with the coupling coefficient between the transmitting circuit and the receiving circuit, and is/>