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Article

Improved Design of PCB Coil for Magnetically Coupled Wireless Power Transfer

1
School of Marine Electrical Engineering, Dalian Maritime University, Dalian 116026, China
2
Dalian Huarui Heavy Industry Group Co., Ltd., Dalian 116013, China
3
Department of Engineering, University of Leicester, Leicester LE1 7RH, UK
4
Dalian Key Laboratory of Swarm Control and Electrical Technology for Intelligent Ships, Dalian 116026, China
*
Author to whom correspondence should be addressed.
Electronics 2024, 13(2), 426; https://doi.org/10.3390/electronics13020426
Submission received: 24 December 2023 / Revised: 16 January 2024 / Accepted: 18 January 2024 / Published: 19 January 2024

Abstract

:
In recent years, wireless power transfer (WPT) has progressed rapidly in both theory and commercialization. However, existing research into WPT coil design for low-power devices to mitigate the coil offset is limited. A dual-layer printed circuit board (PCB) structure is proposed in this paper to mitigate the coil offset while retaining manufacturing simplicity for practical uses. Specifically, the impacts of key geometric parameters on the coil quality factor and coupling coefficient are analyzed through models and simulations. Equivalent PCB coils were formed for mutual inductance models, and four basic compensation circuits were analyzed. The impacts of changes in coil thickness, line width, turn spacing, and number of turns on the quality factor of PCB coils were analyzed with a fixed outer diameter of the coil. Eleven types of PCB coils were manufactured to verify the simulation results. The offset transmission efficiency can reach 46.6% with an output power of 14.4 W. The PCB coil with improved design could offer remarkable improvements in the WPT system for low-power electronic devices.

1. Introduction

In recent years, the surging demand for ubiquitous electricity is catalyzing innovations in wireless power transfer (WPT) to overcome the constraints of wired charging interfaces, such as frequent plugging and unplugging of charging ports and ageing of wire connections [1]. While WPT commercialization for low-power electronic devices, such as toothbrushes, mobile phones, electric bicycles, and so on, is accelerating, efficiency and universality remain limiting factors restricting its broader adoption [2,3,4,5]. WPT coils have two typical solutions, namely the spatial spiral and the planar spiral structure. Figure 1 shows the two types of coil structures. Although planar geometries pose inherent efficiency challenges relative to spatial coils, they achieve better size and weight reductions through printed circuit board (PCB) integration.
At present, the main types of planar coils are enameled wire coils, Lietz wire coils, and PCB coils. Enameled wires are cheap. However, the skin effect of enameled wire is more pronounced under high-frequency conditions [6]. The skin effect refers to the uneven distribution of current inside a conductor when an alternating current or alternating electromagnetic field is present [7]. The current is concentrated in a thin layer on the surface of the conductor; the closer it is to the surface of the conductor, the higher the current density, and the smaller the actual current inside the conductor [8]. As a result, the resistance of the conductor is higher, increasing its loss power [9]. Litz wire coils are suitable for large electrical equipment. However, under high-frequency conditions, the proximity effect of the Litz line is more pronounced. The proximity effect refers to the uneven distribution of current on the cross-section of a conductor when subjected to high AC voltage. The skin and proximity effects of PCB coils in the same environment have small impacts and small sizes, and PCB coils exhibit good stability, making them a good choice for application in mobile electronic devices [10,11]. In addition, compared to enameled wire coils and Litz wire coils, PCB coils have a smaller volume, better stability, and higher manufacturing accuracy. This is convenient for the study of improved designs of the PCB coil’s geometric structure.
Various studies have been carried out on flat coils, both round and square. Jacek [12] calculated the influence of the coil resistance on the power and efficiency of a planar spiral-coil WPT system. It was shown that it was better to accept the skin effect than to reduce the wire diameter for the low-power WPT estimation. An equivalent circuit was also proposed, represented by a single WPT cell, which yielded a simpler and faster solution for a periodic distribution of low-power circular planar coils and square planar coils [13]. Nahed et al. [14] investigated the application of quasi-elliptic curves in designing the transmitter and receiver coils of WPT circuits. The Neuman formula was used to calculate the self-inductance, mutual inductance, and coupling coefficient for each specific geometry and turn location. Their approach could achieve smooth and easily manufacturable coils with higher coupling coefficients, thereby increasing the WPT efficiency. Guan et al. [15] proposed a multi-relay WPT system based on self-compensating PCB planar spiral coil. The total transfer distance of the system is 1.1 m. Jeong et al. [16] designed a smartwatch strap wireless charging system with a flexible PCB coil that has 215 μm thickness and dimensions of 54.5 mm × 16 mm. The WPT charging system had a resonance frequency of 100 kHz, and it achieved a 30% DC-DC power transfer efficiency and an exposed magnetic field of 270 mG. Binma et al. [17] investigated some coil parameters, such as the inter-layer and turn spacing of the layered DD coil, to determine how they influence the inductance, which influences the WPT efficiency. It was deduced that the start radius of the layered DD coil is directly proportional to the inductance. Chen and Zhao [18] used the simplified particle element method and the finite element method to analyze a double-layer printed spiral coil. They discussed the skin effect, the proximity effect, and the dielectric loss in the substrate to reduce the coil loss and improve the quality factor. Wang et al. [19] proposed a planar coil that utilized parallel-connected multilayer printed circuit boards to generate large parasitic capacitance for a resonant wireless power transfer system. Benefitting from the large parasitic capacitance, the resonant frequency of the system was reduced to below 200 kHz.
Taken together, it has been demonstrated that the power transfer efficiency of PCB coils is highly affected by the turn spacing, the thickness of PCB board, the line width, the number of turns, and the shape of turns. However, existing research into WPT coil design for low-power devices to mitigate the coil offset is limited. Therefore, a dual-layer printed circuit board structure is proposed in this paper to mitigate the coil offset while retaining manufacturing simplicity for practical uses. This improved design study results in PCB coils with a higher offset transmission efficiency in low-power WPT systems.

2. Analysis of the Compensation Network and Coil Parameters

The structure of the wireless power transmission system is depicted in Figure 2. In Figure 2, block A represents the DC power supply; block B represents the inverter circuit; block C and block E are compensation networks [20]; block D is a mutual inductance coil, which is a device for power transmission; block F is a rectifier circuit; and block G represents the electrical equipment.
A magnetic coupling structure is used to transmit power through alternating magnetic fields in high-frequency resonant circuits. The alternating magnetic field can be divided into near and far regions, with magnetic induction being the main source in the near region and radiation being the main source in the far region [21]. Energy is emitted outwards in the form of electromagnetic waves. Magnetic coupled wireless power transfer technology utilizes near-field transmission of energy. When the operating frequencies of the transmitting and receiving circuits are the same, energy can be effectively emitted. In wireless power transfer systems, the transmitting and receiving coils undertake the task of power transmission and are important links that affect power transfer. This article will focus on the coupling coils.

2.1. Coupling Coil Circuit Model

The mutual inductance circuit model of the coupling coil is shown in Figure 3. US is the AC power supply at the transmitting coil, I1 and I2 are the currents of the transmitting and receiving circuits, L1 and L2 are the self-inductances of the transmitting and receiving coils, and R1 and R2 are the coil resistances of the transmitting and receiving coils, respectively. Mutual inductance M is used to represent the degree of coupling between the two coils [22].
The total impedance expression of the receiving end circuit is shown in Equation (1), where ω denotes the working angular frequency [23].
Z s = j ω M I 1 I 2 = j ω L 2 + R 2 + R L
Reflection impedance is the influence of the receiving end circuit on the transmitting end circuit and is expressed in Equation (2).
Z r = j ω M I 2 I 1 = ω 2 M 2 Z s = R r + j X r
The real and imaginary parts reflecting impedance are shown in Equations (3) and (4).
R r = ω 2 M 2 ( R 2 + R L ) ω 2 L 2 2 + ( R 2 + R L ) 2
X r = L 2 ω 2 M 3 ω 2 L 2 2 + ( R 2 + R L ) 2
Wireless power transmission works similarly to a transformer, but unlike a transformer, the distance between the transmitting and receiving of wireless power is relatively large. Increasing the magnetic leakage will increase the reactive power of the system and thus the energy loss of the system. Therefore, the transmission efficiency must be improved by adding compensation capacitors to both ends.

2.2. Compensation Circuit

The reactive power compensation of the circuit is usually constructed by increasing the compensation capacitance. Because the position of the compensation capacitor in the circuit differs, its effect also differs. According to the position of the compensation capacitor, it can be categorized as series or parallel, and the receiver and transmitter can also choose whether to add to it. Therefore, the capacitor can be divided into single-sided transmitters in series and parallel transmitters [24]. The receiver is connected in series and in parallel. Bilateral compensation can be divided into series series (SS), series parallel (SP), parallel series (PS), and parallel parallel (PP). Several circuit diagrams of bilateral compensation are shown in Figure 4.
Next, we analyze the bilateral compensation circuit. When compensating capacitors are added to the receiving circuit, Zs1 and Zr1 are used to represent the total impedance of the receiving circuit and the reflected impedance of the transmitting circuit. Rr1 and Xr1 are used to represent the reflected impedance and reactance at the transmitting circuit [25]. When the compensating capacitor at the receiving end is connected in series to the circuit, the total impedance and reflection impedance at the receiving transmitter can be represented by Equations (5) and (6).
Z s 1 = j ω L 2 + 1 j ω C 2 + R L
Z r 1 = C 2 2 M 2 ω 4 R L + j [ C 2 M 2 ω 3 ( L 2 C 2 ω 2 1 ) ] ω 2 C 2 2 R L 2 ( L 2 C 2 ω 2 1 ) 2
The reflection impedance Rr1 and reflection reactance Xr1 of the transmitting circuit are represented by Equations (7) and (8), respectively.
R r 1 = C 2 2 M 2 ω 4 R L ω 2 C 2 2 R L 2 + ( L 2 C 2 ω 2 1 ) 2
X r 1 = C 2 M 2 ω 3 ( L 2 C 2 ω 2 1 ) ω 2 C 2 2 R L 2 + ( L 2 C 2 ω 2 1 ) 2
The above two equations illustrate that when the parameters are connected as in Equation (9), the reactance is reflected as zero. At this time, the receiving compensation circuit is in a resonant working state.
L 2 C 2 ω 2 1 = 0
Similarly, using the same algorithm, when the compensating capacitors of the receiving circuit are connected in parallel, the total impedance, reflection impedance, reflection resistance, and reflection reactance of the receiving end are as shown in Equations (10), (11), (12), and (13), respectively:
Z s 1 = j ω L 2 + 1 j ω C 2 + 1 R L
Z r 1 = ω 2 M 2 R L [ L 2 C 2 ω 2 ( 1 L 2 C 2 ω 2 ) ] + j M 2 ω 3 [ L 2 C 2 ( 1 L 2 C 2 ω 2 ) R L 2 ] ω 2 L 2 2 ( 1 L 2 C 2 ω 2 ) R L 2
R r 1 = ω 2 M 2 R L [ L 2 C 2 ω 2 + ( 1 L 2 C 2 ω 2 ) ] ω 2 L 2 2 + ( 1 L 2 C 2 ω 2 ) R L 2
X r 1 = M 2 ω 3 [ L 2 C 2 ( 1 L 2 C 2 ω 2 ) R L 2 ] ω 2 L 2 2 + ( 1 L 2 C 2 ω 2 ) R L 2
By incorporating the equation for resonance, the reflection resistance and reflection impedance of the receiver with the compensation capacitor can be obtained. The parameters are defined in Table 1.
When compensating capacitors are connected in parallel, the reflected impedance is not zero; it is related to the coil mutual inductance and self-inductance of the receiving end coil, and the reflected impedance is capacitive. In contrast, when the capacitors are connected in series, the reflected impedance is resistive. Therefore, to compensate for the reactive power, capacitors should be connected in series at the receiving end for compensation.
This same method can be used to calculate the parameter values when the transmitter is connected in series. The input impedance at this point is expressed by Equation (14). Additionally, the data in Table 1 illustrates that when the receiving end is a compensation capacitor connected in series, the input impedance is as expressed by Equation (15).
Z in = j ω L 1 + 1 j ω C 1 + Z r
Z in = ω 2 M 2 R L + j ( ω L 1 1 ω C 1 )
Equation (15) illustrates that the input impedance always has an imaginary part; therefore, reactive power is always present. When Equation (16) is satisfied, the transmitting end is in a resonant state; it should simultaneously meet the resonance formula of the receiving end. This is used to ensure that the entire circuit of the system is in a resonant state [26].
ω L 1 1 ω C 1 = 0
The size of the series compensation capacitor at the starting emitter can be calculated as:
C 1 = 1 ω 2 L 1
The capacitance values are calculated under the other three conditions while ensuring that the circuit operates in a resonant state. The compensation capacitance values for different compensation methods are shown in Table 2.
Table 2 reveals the following:
The compensation capacitance values of the PS and PP compensation methods are related to the load resistance value. To ensure that the circuit operates in a resonant state, these two compensation methods are not suitable for this study. When the compensation method is SP, the compensation capacitance value is related to the mutual inductance of the coil. When the position of the coil changes, the mutual inductance also changes accordingly, causing the resonance state to change. When the compensation method is SS, the compensation capacitance value is only related to the coil self-inductance and frequency, making this value easy to fix. Therefore, in this article, the SS compensation method is adopted to optimize the coil parameters. The coupling coil mutual inductance circuit model of the SS compensation method is shown in Figure 5.
The total impedance of the receiving end circuit and the total impedance of the transmitting end circuit are calculated using the equation for resonance mentioned above. Equations (18) and (19) are given as follows.
Z s = R 2 + R L
Z in = R 1 + ω 2 M 2 R 2 + R L
The current I1 at the transmitting end is shown in Equation (20).
I 1 = U s Z in = ( R 2 + R L ) U s ω 2 M 2 + R 1 ( R 2 + R L )
The current I2 of the receiving end circuit is calculated according to Equation (1), as shown in Equation (21).
I 2 = j ω M I 1 Z s = j ω M U s ω 2 M 2 + R 1 ( R 2 + R L )
By calculating the current, the power Pout and energy transmission efficiency η of the receiving circuit can be obtained, as shown in Equations (22) and (23), respectively.
P out = I 2 2 R L = ω 2 M 2 U s 2 R L [ ω 2 M 2 + R 1 ( R 2 + R L ) ] 2
η = P out I 1 2 Z in = ω 2 M 2 R L ( R 2 + R L ) [ ω 2 M 2 + R 1 ( R 2 + R L ) ]
The transmission efficiency of the coil is related to the system’s operating frequency, load resistance, coil mutual inductance, and coil resistance. To further improve the efficiency of the method, this study is primarily focused on changing the coil structure parameters.
For wireless charging systems, the operating frequency of the system is generally fixed. According to the Qi standard formulated by the Wireless Charging Alliance (WPC), the charging frequency of electric vehicles, smart homes, tablets, mobile phones, and other electronic products is around 85 kHz. Based on this standard and combined with actual experimental equipment and other conditions, this article sets 100 kHz as the charging frequency for the wireless charging coil.
Under the condition of determining the operating frequency, the transmission power and efficiency are still related to multiple parameters. Through MATLAB simulation of Equations (22) and (23) under the condition of controlling variables, the coil mutual inductance changes from 0 to 40 uH, the input voltage is 12 V, and the coil resistance is set to 0.5 Ω. The curves obtained under the load resistance of 2.5 Ω, 5 Ω, 7.5 Ω, and 10 Ω are shown in Figure 6.

3. Optimization of PCB Coil Structure Parameters

Coupling coils are primarily planar spiral coils and spatial spiral coils. Spatial spiral coils, often used for equipment with a cylindrical shape, are installed on vertical structures in the equipment and occupy large spaces. Flat spiral coils, used in most electronic and electrical equipment, are installed on flat structures in equipment and occupy small spaces. Planer spiral coils are more suitable for the PCB coil structure studied in this article [27].
The flat coil is primarily circular or square in shape, as shown in Figure 7.
To compare the advantages and disadvantages of circular planar coils and square planar coils, 3D simulation models of multiturn circular planar coils and square planar coils are established in the finite element simulation softwareANASYS Electronics Desktop 19.2 Maxwell. The set solution type is Eddy Current (Alternating Current Field). The set solution setup is Iterative Solver. The initial mesh setting is auto mesh method. The curved surface meshing is using Slider. The computational space is necessary to draw a large air box (with a length of three times the maximum side length of the coil; this is not a strict number, meaning that the box only needs to be large enough). The boundary is Integrated Zero Tangential H Field, and it is necessary to set Eddy Effects on the software.
To avoid errors during comparison, the area size, wire diameter, number of turns, and turn spacing of the two coils are set to be consistent when the coil model is established. The simulated magnetic field cloud map obtained through simulation analysis is shown in Figure 8.
The parameters of the circular and square planar coils and the simulation results of the coil shapes are shown in Table 3.
The inductance value of the circular coil is slightly higher than that of the square coil. The resistance of the circular coil is smaller than that of a square coil, the magnetic field distribution is more uniform, and the convergence is better. Therefore, planar circular coils are ideal for most wireless power transfer applications. The radius of copper wires is generally larger, so this article chose a PCB coil with a thin thickness. Moreover, the volume of the PCB coil is small, and the manufacturing process for PCB is precise, making it suitable for small electronic devices.
The cross-section of the circular coil designed through PCB is shown in Figure 9. N is the number of coil turns, Dout is the outer diameter of the coil, Din is the inner diameter of the coil, P is the coil turn spacing, w is the coil wire width, h is the thickness of the copper wire laid on the PCB, and h1 is the thickness of the PCB.
The formula for calculating the depth of the skin effect of wires made of copper material at different temperatures [28] is presented in Equation (24).
d cu = { 66 f ,     T = 25   ° C 76 f ,     T = 100   ° C
The wire diameter length of the PCB coil is:
l = π ( D out + D in ) 2 N
The average wire diameter of the coil is:
D avg = D out + D in 2
The defined coil filling coefficient is:
β = D out D in D out + D in
The DC resistance of the coil is expressed as:
R dc = l w σ h
The AC resistance of the coil under high-frequency conditions is expressed as:
R ac = R dc h d ( 1 e h d )
Incorporating the DC resistance expression into Equation (29) yields:
R ac = l ω σ d ( 1 e h d )
where σ is the conductivity of the coil wire, and d is the depth of the wire skin effect.
The change in coil resistance was obtained by changing the diameter of the wire from which the coils were wound. In addition, the size of the coil, the number of turns, and the distance between the transmitting and receiving planes can also change the coil resistance. With a detailed analysis, the results showed that the highest efficiency was obtained for a wire diameter of 200 μm (which means the lowest coil resistance). The lowest efficiency was obtained for the smallest wire diameter (100 µm, which has the highest coil resistance). By increasing the diameter of the wire and reducing the coil resistance, a higher WPT system efficiency was obtained.
When the load size is constant, the value reflecting the resistance gradually increases with increasing frequency, and finally, the increasing trend slows and approaches a certain value. For example, when the load is 7.5 Ω and the frequency is approximately 100 kHz, the trend of increasing resistance with frequency becomes slower. Therefore, after determining the load resistance, continuously increasing the system operating frequency has little effect on improving the system efficiency, and the higher the system operating frequency is, the greater the losses generated by the coils. The greater the mutual inductance between the coupling coils is, the greater the reflecting resistance. The mutual inductance is closely related to the structure of the coils and the relative position between the two coils. Therefore, to improve the transmission efficiency of the system, it is necessary to both add compensation circuits to compensate for reactive power in the system and improve the design on the structure of the coupling coils.
Magnetic coupled wireless power transfer technology utilizes near-field transmission of energy. The electromagnetic wave studied in this article has a frequency of 100 kHz, a wavelength of approximately 3 km, and a near-field radius of approximately 9 km. Therefore, in practical applications, this study only considers the near field.
The resistance of a coil when high-frequency AC power is incorporated is related to the wire diameter length, coil thickness, and skin effect depth of the coil. Therefore, simulation research must be conducted on the structural parameters of the coil, and the impacts of changes in coil structural parameters on the coil resistance must be examined.
The inductance of a PCB planar circular coil is expressed as:
L = μ 0 D avg N 2 2 [ ln ( 2.46 β ) + β 2 5 ]
Before the coil parameters are examined, the quality factor Q and coupling coefficient k are introduced:
Q = ω L R
k = M L 1 L 2
Substituting Equations (32) and (33) into Equation (23) yields:
η = Q 1 Q 2 k 2 R 1 R 2 R L [ R 1 ( R 2 + R L ) + Q 1 Q 2 k 2 R 1 R 2 ] R 2 + R L
Simplifying Equation (34) yields Equation (35).
η = Q 1 Q 2 k 2 ( 1 + R L R 2 + Q 1 Q 2 k 2 ) ( 1 + R 2 R L )
The first partial derivative of RL in Equation (35) is zero, and the second order partial derivative is less than zero. The following can be concluded:
η = Q 1 Q 2 k 2 ( 1 + 1 + Q 1 Q 2 k 2 ) 2
Q1Q2k2 is defined as the strong coupling coefficient [29] of the coil. Equation (36) reveals that the larger the strong coupling coefficient is, the higher the transmission efficiency of the coil. Previous analysis has shown that the design of the coil must consider the degree of coupling between the coils in addition to its quality factor. The quality factor and the coupling coefficient of the coil correlate with the strong coupling coefficient. Therefore, maximizing the strong coupling coefficient has become a research goal.
The structural parameters of the receiving and transmitting ends of the PCB coil studied in this article are the same, and Q1 and Q2 are also the same. The efficiency of the coil can be simplified as:
η = ( k Q ) 2 [ 1 + 1 + ( k Q ) 2 ] 2
A simulation model is formed with two coils placed in parallel and coaxially with a distance H of 4.5 cm, as shown in Figure 10.
The structural parameters of PCB planar coils generally include the thickness of the coil, turn spacing, line width, and number of turns. Therefore, this article will use the control variable method to simulate the structural parameters of the coil.

3.1. Coil Thickness

There are generally three copper thicknesses used for PCB flat coils: 0.035 mm, 0.05 mm, and 0.07 mm. The outer diameter of the fixed coil is set as 9 cm, the coil line width is set as 2 mm, the coil turns are set as 7, and the frequency is set as 100 kHz. The self-inductance and resistance values of the coil obtained by simulating different copper thicknesses are shown in Table 4, Table 5 and Table 6. The simulation data of the quality factor of the coil with different thicknesses are shown in Figure 11.
Table 4, Table 5 and Table 6 show that for the same turn spacing, the self-inductance of the coil remains almost unchanged with increasing thickness, indicating that the thickness does not affect the self-inductance of the coil. The resistance value of the coil decreases with the thickness, indicating that the resistance value of the coil is proportional to the thickness. When the thickness is the same at different turn spacings, the self-inductance and resistance values of the coil decrease with the turn spacing.
Due to the working frequency of the coil discussed in this article being 100 kHz and the thinness of the PCB coil, the skin effect of the coil was not obvious. As shown in Figure 11, under the same turn spacing conditions, the quality factor of the coil increases with the coil thickness. This is because under the premise of constant coil self-inductance and working frequency, the smaller the resistance of the coil is, the greater the quality factor of the coil. Therefore, 0.07 mm was chosen as the design’s coil thickness.

3.2. Coil Turn Spacing

The outer diameter of the fixed coil is set as 9 cm, the coil thickness is set to 0.07 mm, the coil line width is set as 2 mm, the coil turns are set as 7 turns, and the frequency is set as 100 kHz. The coil turn spacing changes from 0.5 mm to 4 mm in steps of 0.5 mm, and a simulation with a coil turn spacing of 0.2 mm is conducted. The simulation results are shown in Figure 12.
Figure 12a illustrates that as the pitch between the coils increases, the quality factor of the coils decreases, and the coupling coefficient between coils first increases and then decreases, exhibiting a maximum coupling coefficient. Figure 12b shows the simulation data curve of the strong coupling coefficient of the coil. The strong coupling coefficient curve shows a decreasing trend. Considering the requirements of the PCB manufacturing process, the coil turn spacing is set as 0.2 mm in this article.

3.3. Coil Line Width

The outer diameter of the fixed coil is set as 9 cm, the coil thickness is set as 0.07 mm, the coil turn spacing is set as 0.2 mm, the coil turns are set as 7 turns, the frequency is set as 100 kHz, and the coil line width changes from 0.5 mm to 4.5 mm in steps of 0.5 mm. The simulation results are shown in Figure 13.
Figure 13a illustrates that as the coil width increases, the quality factor of the coil first increases and then decreases. The maximum value occurs when the coil width is 2.5 mm, and the coupling coefficient between coils first increases and then decreases. Figure 13b shows the simulation data curve of the strong coupling coefficient of the coil. The strong coupling coefficient first increases and then decreases. In this figure, the maximum value occurs when the coil width is 2.5 mm. Because the simulated curve in Figure 13 is based on the order of magnitude of the coil line width changing in steps of 0.5 mm, to clarify whether the strong coupling coefficient of the coil is maximized at a line width of 2.5 mm or at a certain line width near 2.5 mm, the simulation values for the line width from 2.4 mm to 2.9 mm in steps of 0.1 mm are shown in Table 7.
Table 7 shows that the maximum value of the strong coupling coefficient of the coil is achieved when the line width is 2.8 mm, which differs slightly from the maximum value of the strong coupling coefficient in Figure 13b. Therefore, the coil line width is set as 2.8 mm in this article.

3.4. Coil Turns

The outer diameter of the fixed coil is set as 9 cm, the coil thickness is set to 0.07 mm, the coil turn spacing is set as 0.2 mm, the coil line width is set as 2.8 mm, and the frequency is set as 100 kHz. The number of coil turns changes from 5 to 14 in steps of 1. The corresponding relationship between the coil filling coefficient and the number of turns and the inner diameter of the coil is shown in Table 8.
The simulation data obtained by simulating different turns of the coil are shown in Figure 14.
Figure 14b depicts a simulation data curve of the strong coupling coefficient of the coil. The strong coupling coefficient first increases and then decreases. The filling coefficient of the coil is 0.36, which means that the strong coupling coefficient reaches its maximum when the number of coil turns is equal to 8. Therefore, the number of coil turns is set as 8 in this paper.
Previous research has shown that regardless of the outer diameter of the coil, after setting the coil line width and turn spacing, the inner diameter of the coil and the optimal number of turns of the coil can be determined using the formula for the coil filling coefficient and the optimal value of the coil filling coefficient.

4. Research on the Offset Characteristics of PCB Coils

The deviation of the coil significantly impacts the coupling coefficient between coils, which in turn affects the strong coupling coefficient of the coil. After the coil is offset, the magnetic field weakens, decreasing the coupling degree between the transmitting end coil and the receiving end coil and decreasing the coupling coefficient between the coils. To reduce the adverse effects of coil offset, a double-layer PCB coil, which lays coils on both the top and bottom layers of the PCB board, is designed in this paper.
Figure 15 depicts a top view of the top and bottom layers of a double-layer PCB coil. The red line is on top lay of the PCB. The blue line is on the bottom lay of the PCB. Two design methods for the bottom layers of the coil are proposed. The current directions of the top and bottom layers of the coil are the same. A, B, C, D, E, and F in the figure represent the interface between the coil and the external connection. Figure 15a is the top view of the coil, Figure 15b is the top view of the coil bottom in Scheme 1, and Figure 15c is the top view of the coil bottom in Scheme 2. The bottom layer of the coil adopts Scheme 1, where interface C of the bottom layer coil is connected to interface A of the top layer, and interfaces B and D are connected to external circuits. When the bottom layer of the coil adopts Scheme 2, interface E of the bottom layer coil is connected to interface A of the top layer, and interfaces B and F are connected to external circuits.
To simulate the offset phenomenon in real scenarios, four simulation studies were conducted: coaxial parallel offset, coaxial nonparallel offset, different axes of parallel offset, and different axes of nonparallel offset. We next explore whether the transmission efficiency of this structure is better than that of single-layer PCB coils.

4.1. Coaxial Parallel Offset

First, the coaxial parallel offset of the coil is studied. Figure 16 is a schematic diagram of the coaxial parallel offset of the coil. The center of the transmitting coil is fixed at the coordinate origin, and the transmitting and receiving coils in the figure remain coaxial and fixed.
When coaxial parallel offset simulation analysis is conducted on the coil, the outer diameter of the coil is fixed at 9 cm, the coil thickness is set as 0.07 mm, the coil turn spacing is set as 0.2 mm, the coil line width is set as 2.8 mm, the number of coil turns is set as 8, the operating frequency is set as 100 kHz, and the offset distance of the coil changes from 1 cm to 7 cm. Figure 17 depicts a partial model diagram of the simulation of the coaxial parallel offset of the coil.
Table 9 provides the simulation values of the quality factor, self-inductance, and resistance of the single-layer coil, Scheme 1 coil, and Scheme 2 coil. The simulation data of the single-layer coil, Scheme 1, and Scheme 2 double-layer coils are depicted in Figure 18.
Table 9 shows that the quality factor of the double layer coil in Scheme 1 is higher than that of the other two types of coils, and the coil resistance is the smallest among the three types of coils. The self-inductance value of the double-layer coil in Scheme 2 is significantly higher than that of the other two types of coils, and the coil quality factor is higher than that of the single-layer coil; however, its resistance is significantly higher.
Figure 18c depicts a simulation data graph of the transmission efficiency of the three types of coils. As the offset distance increases, the transmission efficiency of the coil decreases. For Scheme 2, the transmission efficiency of the double-layer coil is higher than that of the other two types of coils. At the offset distance of the coil radius, the transmission efficiency is 48%, which is approximately 8% higher than that of the single-layer coil at the same distance.

4.2. Coaxial Nonparallel Offset

Figure 19 depicts a schematic diagram of the coaxial nonparallel offset of the coil. The center of the transmitting end coil is fixed at the coordinate origin, and the transmitting end and receiving end coils in the figure remain coaxial and fixed. The receiving end coil undergoes an angular offset in the z-axis direction.
When simulation analysis is conducted on the coaxial nonparallel offset of the coil, the basic simulation parameters of the coil are consistent with those of the coaxial parallel offset, with a working frequency of 100 kHz. The offset angle of the coil changes from 0 degrees to 80 degrees, and the offset distance changes from 4.5 cm to 7 cm. During the simulation, the coil is assumed to be offset in the positive direction of the z-axis. Figure 20 depicts a partial model diagram of the coil coaxial nonparallel offset simulation. The simulation data of the single-layer coil and the Schemes 1 and 2 double-layer coils are shown in Figure 21.
The coupling coefficients of the single-layer coil and the double-layer coil in Scheme 1 are basically identical. At the same offset angle, the coupling coefficients and strong coupling coefficients of the double-layer coil in Scheme 2 are greater than those of the other two coils, and the strong coupling coefficient of the single-layer coil is the smallest. The transmission efficiency of the double-layer coil in Scheme 2 is higher than that of the other two coil structures.
Figure 21d shows the data comparison curve of the strong coupling coefficient under different offset angles when the coil offset distance is 5.5 cm. Scheme 2 has the largest strong coupling coefficient, while Scheme 1 has a slightly smaller strong coupling coefficient than Scheme 2. The single-layer coil has the smallest strong coupling coefficient. These results indicate that Scheme 2 has a stronger anti-offset ability than the other two coils.

4.3. Parallel Offset of Different Axes

Figure 22 depicts a schematic diagram of the parallel offset of different axes of the coil. The center of the transmitting end coil is fixed at the coordinate origin. The transmitting end and receiving end coils in the figure have different axes, and the receiving end coil experiences parallel offset in the horizontal direction. The center of the coil is assumed to remain on the y-axis when the receiving end coil is offset.
When simulation analysis is conducted on the parallel offset of different axes of the coil, the basic simulation parameters of the coil are consistent with those of the coaxial parallel offset. The operating frequency is set as 100 kHz, and the vertical distance between the two coils is fixed at 4.5 mm. During simulation, the lower coil is assumed to be offset in the positive y-axis direction, and the offset distance of the coil is assumed to change from 0 to 5 cm. Figure 23 depicts a partial model diagram of the simulation of the coaxial nonparallel offset of the coil. The simulation data of the single-layer coil and Schemes 1 and 2 double-layer coils are shown in Figure 24.
Figure 24c depicts a simulation data graph of the transmission efficiency of three types of coils. As the offset distance increases, the transmission efficiency of the coils decreases. The transmission efficiency of the double-layer coils in Scheme 2 is higher than that of the other two coils at the same offset distance.

4.4. Different Axes Are not Parallel Offset

Figure 25 depicts a schematic diagram of the nonparallel offset of different axes of the coil. The center of the transmitting end coil is fixed at the coordinate origin. The transmitting end and receiving end coils in the figure have different axes, and the receiving end coil is offset in the y-axis direction with an angle. The center of the coil is assumed to remain on the y-axis when the receiving end coil is offset.
When simulation analysis is conducted on the nonparallel offset of different axes of the coil, the basic simulation parameters of the coil are consistent with those of the coaxial parallel offset, with a working frequency of 100 kHz, a fixed vertical distance of 4.5 mm between the two coils, a variation in the offset angle of the coil from 0 degrees to 80 degrees, and a variation in the horizontal offset distance from 0 to 4 cm. During the simulation, the coil is assumed to be offset in the positive direction of the y-axis. Figure 26 depicts a partial model diagram of the simulation of different axes used for the nonparallel offsets of the coil. The simulation data of the single-layer coil and Schemes 1 and 2 double-layer coils are shown in Figure 27.
Figure 27a is a simulation data graph of three types of coil coupling coefficients, Figure 27b is a simulation data graph of three types of coil strong coupling coefficients, and Figure 27c is a simulation data graph of three types of coil transmission efficiency. Figure 27a–c illustrate that when the deviation angle is approximately 0 to 30 degrees, the coupling coefficient, strong coupling coefficient, and coil transmission efficiency remain basically unchanged, and a slight increasing trend is exhibited. After the angle deviation is beyond 30 degrees, excessive angle deviation occurs, and the magnetic field relationship between coils weakens; the coupling coefficient, strong coupling coefficient, and coil transmission efficiency begin decreasing; and the decreasing trend accelerates [30]. The coupling coefficients of the single-layer coil and the double-layer coil in Scheme 1 are basically the same. At the same offset angle, the coupling coefficient and strong coupling coefficient of the double-layer coil in Scheme 2 are greater than those of the other two coils, and the strong coupling coefficient of the single-layer coil is the smallest. The transmission efficiency of the double-layer coil in Scheme 2 is higher than that of the other two coil structures. As the offset distance increases, the coupling coefficient, strong coupling coefficient, and transmission efficiency of the coil gradually decrease [31].
Figure 27d shows the data comparison curve of the strong coupling coefficient under different offset angles when the coil offset distance is 1 cm. Scheme 2 has the largest strong coupling coefficient, while Scheme 1 has a slightly smaller strong coupling coefficient than Scheme 2. The single-layer coil has the smallest strong coupling coefficient, indicating that Scheme 2’s double-layer coil has a stronger anti-offset ability than the other two coil structures.
These results indicate that the anti-offset characteristics of the coil structure in Scheme 2 are better than those of the Scheme 1 and single-layer coils, and the wireless power transmission efficiency is better than that of single-layer PCB coils.

5. Experimental Verification

In this section, experimental verification is conducted on the Maxwell simulation analysis of PCB coils. Based on the analysis in the previous section, a physical PCB coil is constructed, and the quality factor of the PCB coil and the coupling coefficient at different spatial positions of the coil are evaluated [32,33]. A comparison and analysis are conducted using simulation data, and a wireless power transmission system experimental platform is built.

5.1. Coil Experimental Model

Based on the theory discussed in the previous sections, 11 types of PCB coils were manufactured to verify the research results. Figure 28 shows 9 types of single-layer coils. Figure 29 shows 2 types of double-layer coils.
The structural parameters of the 11 sets of coils are shown in Table 10. All coils have an outer diameter of 9 cm. Coil 1 and coil 3 are the experimental groups for studying coil thickness; coil 2, coil 3, and coil 4 are the experimental groups for studying coil turn spacing; coil 5, coil 6, and coil 7 are the experimental groups for studying coil line width; coil 6, coil 8, and coil 9 are the experimental groups for studying coil turns; and coil 8, coil 10, and coil 11 are the experimental groups for studying coil offset.

5.2. Measurement of Coil Parameters

A digital bridge can be used to measure the parameters of the PCB coil. The experimental platform is shown in Figure 30.
Parameters such as coil self-inductance are measured as shown in Figure 30a. Mutual inductance is measured as shown in Figure 30b.
The mutual inductance can be calculated using the forward and reverse measurement results at the same position. Meanwhile, the obtained coupling coefficient can be calculated using Equations (38) and (39).
M = L L 4
k = L L 4 L
In these equations, L represents the self-inductance value of the coil, L′ represents the measured inductance of two coils in forward series, and L″ represents the measured inductance of two coils in reverse series.
The strong coupling coefficient calculated based on the theoretical formula is compared with the simulation value when the coil spacing is 4.5 cm.
The data in Table 11 illustrates that the changes in coil parameters are consistent with the theoretical analysis, which validates the research on the impacts of PCB coil parameters on wireless power transmission efficiency in this paper.
The proposed double-layer coil structure is validated to address the impact of coil offset on transmission efficiency. Table 12 provides the simulation and experimental coil parameters for the single-layer coils and Schemes 1 and 2 double-layer coils.
To verify the effectiveness of the double-layer coil in resisting offset, the parameters are measured on the transmitting end coil and the receiving end coil at different spatial positions using a digital bridge. The simulation data and measurement calculation data of the strong coupling coefficient of the coil are compared, as shown in Figure 31.
Figure 31 shows that the changes in the measured and calculated values are basically the same as those in the simulation data. The strong coupling coefficient of Scheme 2 is the largest, while the strong coupling coefficient of the single-layer coil is the smallest. This confirms the previously drawn conclusion and shows that the Scheme 2 coil exhibits a strong anti-offset ability.
The standard deviations of multiple parameters under four different offset states are shown in Table 13. The standard deviations are less than 0.4, which proves that the results of this experiment are consistent with those of the simulation.
Figure 32 shows the experimental platform.
The parameters of the experimental system are presented in Table 14.
Then, an oscilloscope is used to measure the experimental data, as shown in Figure 33.
Figure 33a shows the waveform output by the inverter. The red waveform represents the voltage at the transmitting end, and the blue waveform represents the current at the transmitting end. Figure 33b shows the load waveform of the receiver coil, with red indicating the voltage waveform of the receiver and blue indicating the current waveform of the receiver. The output power is calculated to be 14.4 W, and the coil transmission efficiency is calculated to be 74.6%. The voltage and current are in phase, and the system has reached a resonant operating state.
The vertical distance is changed in space, and the curve between the offset distance and transmission efficiency is drawn, as shown in Figure 34.
During measurement, there may be errors between the experimental values and the software simulation values due to the equipment and the environment. The standard deviation can be used to verify whether the experimental results match the simulation data. The transmission efficiency errors between the experimental and simulation results at different offset distances are shown in Figure 34, and it is shown that the results were acceptable.
A comparison of the transmission efficiency of the PCB coils with that of other devices in the literatures is shown in Table 15. The coil sizes used during the study were different. Therefore, the transmission efficiency of the coils when the vertical offset distance is 1/2 of the coil size is selected as the reference value and is represented as the “offset transmission efficiency (%)” in Table 15.
The research results of the coil in this article have been verified.

6. Conclusions

Wireless power transmission technology exhibits flexibility, safety, and reliability and is widely used in many fields. In this paper, the parameter optimization of a small wireless power transmission system based on a PCB is studied. By analyzing the characteristics of several compensation circuits, the most suitable compensation circuit model for PCBs is selected. To improve the transmission efficiency, a strong coupling coefficient is adopted. The strong coupling coefficient is taken as the objective optimization function. Simultaneously, how to increase the transmission efficiency when the coil is offset is examined. The designed double-layer PCB structure improves the anti-offset characteristics of the coil. Finally, a total of 11 groups of PCB coils were fabricated to study the coil structure parameters and coil offset. The parameters were measured by a digital bridge, and the calculation results were compared with the theoretical results. These experimental results indicate that the PCB coil is optimized.

Author Contributions

Conceptualization, Y.F. and Y.Z.; methodology, Y.F.; software, D.J.; validation, Y.F., Y.Z. and D.J.; formal analysis, Y.Z.; investigation, B.J.; resources, Y.F.; data curation, D.J.; writing—original draft preparation, D.J.; writing—review and editing, B.J.; visualization, D.J.; supervision, Z.P.; project administration, Y.F.; funding acquisition, Y.F. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Fundamental Research Funds for the Central Universities, grant number 3132023112, and the Spring Sunshine Plan Research Project of Ministry of Education of China, grant number HZKY20220410.

Data Availability Statement

Data are contained within the article.

Conflicts of Interest

Author Yu Zhu was employed by the company Dalian Huarui Heavy Industry Group Co., Ltd. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

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Figure 1. Two types of coil structures: (a) spatial spiral structure, (b) planar spiral structure.
Figure 1. Two types of coil structures: (a) spatial spiral structure, (b) planar spiral structure.
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Figure 2. Structure diagram of the wireless power transfer system.
Figure 2. Structure diagram of the wireless power transfer system.
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Figure 3. Coupled coil mutual inductance circuit model.
Figure 3. Coupled coil mutual inductance circuit model.
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Figure 4. Circuit figure of the bilateral compensation method: (a) SS-type compensation; (b) SP-type compensation; (c) PS-type compensation; (d) PP-type compensation.
Figure 4. Circuit figure of the bilateral compensation method: (a) SS-type compensation; (b) SP-type compensation; (c) PS-type compensation; (d) PP-type compensation.
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Figure 5. Coupling coil mutual inductance circuit model of the SS compensation method.
Figure 5. Coupling coil mutual inductance circuit model of the SS compensation method.
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Figure 6. Relationship between coil mutual inductance and transmission power and efficiency under different load resistances: (a) coil transmission power; (b) coil transmission efficiency.
Figure 6. Relationship between coil mutual inductance and transmission power and efficiency under different load resistances: (a) coil transmission power; (b) coil transmission efficiency.
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Figure 7. Flat coils with different shapes: (a) circular plane spiral coil; (b) square plane spiral coil.
Figure 7. Flat coils with different shapes: (a) circular plane spiral coil; (b) square plane spiral coil.
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Figure 8. Magnetic field nephogram of plane coils with different shapes: (a) circular plane spiral coil; (b) square plane spiral coil.
Figure 8. Magnetic field nephogram of plane coils with different shapes: (a) circular plane spiral coil; (b) square plane spiral coil.
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Figure 9. Sectional figure of the PCB plane circular coil.
Figure 9. Sectional figure of the PCB plane circular coil.
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Figure 10. Three-dimensional simulation model of the coil.
Figure 10. Three-dimensional simulation model of the coil.
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Figure 11. Quality factor with different thicknesses.
Figure 11. Quality factor with different thicknesses.
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Figure 12. Simulation results of different coil turn spacings: (a) coil quality factor and coupling coefficient; (b) strong coupling coefficient of coil.
Figure 12. Simulation results of different coil turn spacings: (a) coil quality factor and coupling coefficient; (b) strong coupling coefficient of coil.
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Figure 13. Simulation results of different coilline width: (a) coil quality factor and coupling coefficient; (b) strong coupling coefficient of coil.
Figure 13. Simulation results of different coilline width: (a) coil quality factor and coupling coefficient; (b) strong coupling coefficient of coil.
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Figure 14. Simulation data of different coil turns: (a) coil quality factor and coupling coefficient; (b) strong coupling coefficient of coil.
Figure 14. Simulation data of different coil turns: (a) coil quality factor and coupling coefficient; (b) strong coupling coefficient of coil.
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Figure 15. Top view of the double-layer PCB coil: (a) top view of the coil top layer; (b) top view of the coil bottom layer in Scheme 1; (c) top view of the coil bottom layer in Scheme 2.
Figure 15. Top view of the double-layer PCB coil: (a) top view of the coil top layer; (b) top view of the coil bottom layer in Scheme 1; (c) top view of the coil bottom layer in Scheme 2.
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Figure 16. Model figure of coil coaxial parallel offset.
Figure 16. Model figure of coil coaxial parallel offset.
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Figure 17. Schematic figure of coil coaxial parallel offset: (a) offset 3 cm; (b) offset 5 cm; (c) offset 7 cm.
Figure 17. Schematic figure of coil coaxial parallel offset: (a) offset 3 cm; (b) offset 5 cm; (c) offset 7 cm.
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Figure 18. Simulation data of coil coaxial parallel offset: (a) coil coupling coefficient; (b) coil strong coupling coefficient; (c) coil transmission efficiency.
Figure 18. Simulation data of coil coaxial parallel offset: (a) coil coupling coefficient; (b) coil strong coupling coefficient; (c) coil transmission efficiency.
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Figure 19. Schematic figure of coil coaxial nonparallel offset.
Figure 19. Schematic figure of coil coaxial nonparallel offset.
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Figure 20. Model figure of coil coaxial nonparallel offset: (a) offset 5 cm, offset 30 degrees; (b) offset 5 cm, offset 60 degrees; (c) offset 7 cm, offset 30 degrees.
Figure 20. Model figure of coil coaxial nonparallel offset: (a) offset 5 cm, offset 30 degrees; (b) offset 5 cm, offset 60 degrees; (c) offset 7 cm, offset 30 degrees.
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Figure 21. Simulation results of coil coaxial nonparallel offset: (a) coil coupling coefficient; (b) coil strong coupling coefficient; (c) coil transmission efficiency; (d) comparison of strong coupling coefficients at different offset angles under the condition of an offset distance of 5.5 cm.
Figure 21. Simulation results of coil coaxial nonparallel offset: (a) coil coupling coefficient; (b) coil strong coupling coefficient; (c) coil transmission efficiency; (d) comparison of strong coupling coefficients at different offset angles under the condition of an offset distance of 5.5 cm.
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Figure 22. Schematic figure of coil different axes parallel offset.
Figure 22. Schematic figure of coil different axes parallel offset.
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Figure 23. Model figure of different axes used for the parallel offset of coil: (a) offset 1 cm; (b) offset 2.5 cm; (c) offset 4 cm.
Figure 23. Model figure of different axes used for the parallel offset of coil: (a) offset 1 cm; (b) offset 2.5 cm; (c) offset 4 cm.
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Figure 24. Simulation data of coils with different parallel offset axes: (a) coil coupling coefficient; (b) coil strong coupling coefficient; (c) coil transmission efficiency.
Figure 24. Simulation data of coils with different parallel offset axes: (a) coil coupling coefficient; (b) coil strong coupling coefficient; (c) coil transmission efficiency.
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Figure 25. Schematic figure of different axes of nonparallel offset of coils.
Figure 25. Schematic figure of different axes of nonparallel offset of coils.
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Figure 26. Model figure of coil different axes nonparallel offset: (a) offset 2 cm, angle 30 degrees; (b) offset 2 cm, angle 60 degrees; (c) offset 4 cm, angle 30 degrees.
Figure 26. Model figure of coil different axes nonparallel offset: (a) offset 2 cm, angle 30 degrees; (b) offset 2 cm, angle 60 degrees; (c) offset 4 cm, angle 30 degrees.
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Figure 27. Simulation data of coils with different nonparallel offset axes: (a) coil coupling coefficient; (b) coil strong coupling coefficient; (c) coil transmission efficiency; (d) comparison of strong coupling coefficients at different offset angles under the condition of a 1 cm offset distance.
Figure 27. Simulation data of coils with different nonparallel offset axes: (a) coil coupling coefficient; (b) coil strong coupling coefficient; (c) coil transmission efficiency; (d) comparison of strong coupling coefficients at different offset angles under the condition of a 1 cm offset distance.
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Figure 28. Physical figure of a single-layer coil: (a) coil 1; (b) coil 2; (c) coil 3; (d) coil 4; (e) coil 5; (f) coil 6; (g) coil 7; (h) coil 8; (i) coil 9.
Figure 28. Physical figure of a single-layer coil: (a) coil 1; (b) coil 2; (c) coil 3; (d) coil 4; (e) coil 5; (f) coil 6; (g) coil 7; (h) coil 8; (i) coil 9.
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Figure 29. Physical figure of a double-layer coil: (a) coil 10; (b) coil 11.
Figure 29. Physical figure of a double-layer coil: (a) coil 10; (b) coil 11.
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Figure 30. Experimental platform for coil parameter measurement: (a) self-inductance measurement; (b) mutual inductance measurement.
Figure 30. Experimental platform for coil parameter measurement: (a) self-inductance measurement; (b) mutual inductance measurement.
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Figure 31. Simulation data and measurement calculation data of the strong coupling coefficient for coil offset: (a) coaxial parallel offset; (b) coaxial nonparallel offset; (c) parallel offset of different axes; (d) different axes are not parallel offset.
Figure 31. Simulation data and measurement calculation data of the strong coupling coefficient for coil offset: (a) coaxial parallel offset; (b) coaxial nonparallel offset; (c) parallel offset of different axes; (d) different axes are not parallel offset.
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Figure 32. Wireless power transfer system experimental platform.
Figure 32. Wireless power transfer system experimental platform.
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Figure 33. Oscilloscope-measured waveform: (a) voltage (red) and current (blue) waveforms at the transmitting end; (b) load voltage (red) and current (blue) waveform at the receiving end.
Figure 33. Oscilloscope-measured waveform: (a) voltage (red) and current (blue) waveforms at the transmitting end; (b) load voltage (red) and current (blue) waveform at the receiving end.
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Figure 34. Simulation and experimental data on coil transmission efficiency.
Figure 34. Simulation and experimental data on coil transmission efficiency.
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Table 1. Reflecting resistance and reflecting reactance at the receiving end.
Table 1. Reflecting resistance and reflecting reactance at the receiving end.
Receiving Capacitance
Compensation Method
Capacitor in SeriesCapacitor in Parallel
Reflective resistance Rr ω 2 M 2 R L M 2 R L L 2 2
Reflective reactance X0 ω M 2 L 2
Table 2. Different compensation methods for the capacitor value.
Table 2. Different compensation methods for the capacitor value.
Compensation MethodTransmitting End
Compensation Capacitor C1
Receiving End Compensation Capacitor C2
SS 1 ω 2 L 1 1 ω 2 L 2
SP L 2 ω 2 ( L 1 L 2 M 2 ) 1 ω 2 L 2
PS L 1 R L 2 ω 2 ( M 4 + L 1 2 R L 2 ) 1 ω 2 L 2
PP L 1 M 2 L 2 M 4 R L 2 L 2 4 + ω 2 ( L 1 M 2 L 2 ) 2 1 ω 2 L 2
Table 3. Parameters of coils with different shapes.
Table 3. Parameters of coils with different shapes.
Coil ShapeOutside Diameter (cm)Area (cm2)Inductance (uH)Resistance (mΩ)
Circular11.2699.583.72363
Square101003.58393
Table 4. Self-inductance and resistance value of coil with different thicknesses (turn spacing 0.5 mm).
Table 4. Self-inductance and resistance value of coil with different thicknesses (turn spacing 0.5 mm).
Coil Thickness (mm)Self-Inductance (μH)Resistance (mΩ)
0.0355.28402
0.055.26211
0.075.26146
Table 5. Self-inductance and resistance value of coil with different thicknesses (turn spacing 1.5 mm).
Table 5. Self-inductance and resistance value of coil with different thicknesses (turn spacing 1.5 mm).
Coil Thickness (mm)Self-Inductance (μH)Resistance (mΩ)
0.0354.1368
0.054.1189
0.074.08131
Table 6. Self-inductance and resistance value of coil with different thicknesses (turn spacing 2.5 mm).
Table 6. Self-inductance and resistance value of coil with different thicknesses (turn spacing 2.5 mm).
Coil Thickness (mm)Self-Inductance (μH)Resistance (mΩ)
0.0353.21335
0.053.2172
0.073.19119
Table 7. Parameters of coils with different line widths.
Table 7. Parameters of coils with different line widths.
Line Width (mm)2.42.52.62.72.82.9
Quality factor17.2217.3117.3717.4217.4717.38
Coupling coefficient0.11670.11710.11750.11780.11800.1181
Strong coupling coefficient4.044.114.174.214.254.21
Table 8. Relation between coil filling coefficient and turns and inner diameter.
Table 8. Relation between coil filling coefficient and turns and inner diameter.
Fill Factor0.200.250.300.360.430.500.580.660.760.87
Coil turns567891011121314
Inside diameter (mm)60.254.248.242.236.230.224.218.212.26.2
Table 9. Simulation data of the coil quality factor, self-inductance, and resistance.
Table 9. Simulation data of the coil quality factor, self-inductance, and resistance.
Coil TypeQuality FactorSelf-Inductance (uH)Resistance (mΩ)
Single-layer coil18.095.12178
Scheme 1 21.625.13149
Scheme 221.0820.61614
Table 10. Parameters of the coil structure.
Table 10. Parameters of the coil structure.
Coil NumberThickness (mm)Turn Spacing (mm)Line Width (mm)Number of TurnsNumber of Layers
10.0350.5271
2 0.070.2271
30.070.5271
40.071271
50.070.22.771
60.070.22.871
70.070.22.971
80.070.22.881
90.070.22.891
100.070.22.882
110.070.22.882
Table 11. Simulation and measured calculation values of the coil strong coupling coefficient.
Table 11. Simulation and measured calculation values of the coil strong coupling coefficient.
Coil Number123456789
Simulation value0.923.633.362.984.214.254.214.574.55
Measurement calculation value 0.863.393.102.743.904.933.894.234.20
Table 12. Simulated and measured values of the coil quality factor, self-inductance, and resistance.
Table 12. Simulated and measured values of the coil quality factor, self-inductance, and resistance.
ParameterSingle-Layer CoilScheme 1 CoilScheme 2 Coil
Quality factor simulation value18.0921.6121.08
Quality factor measurement value 17.4420.8120.33
Self-perception simulation value (uH)5.125.1320.61
Self-inductance measurement value (uH)5.255.2720.85
Resistance simulation value (mΩ)178152623
Resistance measurement value (mΩ)189159644
Table 13. Standard deviation of multiple parameters under four different offset states.
Table 13. Standard deviation of multiple parameters under four different offset states.
Strong Coupling Coefficient Standard DeviationSingle-Layer CoilScheme 1 CoilScheme 2 Coil
Coaxial parallel offset0.360.370.36
Coaxial nonparallel offset0.040.020.01
Parallel offset of different axes0.050.070.05
Different axes are not parallel offset0.060.040.03
Table 14. Experimental system parameters.
Table 14. Experimental system parameters.
System ParameterValue
Operating frequency98 kHz
Transmitting and receiving end coil self-sensing 20.85 uH
Transmitting and receiving terminal coil resistance0.64 Ω
Compensation capacitance at the transmitting and receiving ends126 nF
Input voltage at the transmitting end12 V
Receiving end load resistance5 Ω
Table 15. Comparison of coil transmission efficiency.
Table 15. Comparison of coil transmission efficiency.
Outer Diameter of CoilsWith Magnetic CoresOperating FrequencyMaximum Transmission Efficiency Offset Transmission Efficiency
This article9 cmNo98 kHz83.7%46.6%
Reference [34]12 cmYes120 kHz65%22%
Reference [35]17.2 cmYes1 MHz95%41%
Reference [36]4.5 cmYes200 kHz81%Below 30%
Reference [37]11.8 cmNo13.56 MHz81.7%Below 30%
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Fu, Y.; Zhu, Y.; Jiang, D.; Ji, B.; Peng, Z. Improved Design of PCB Coil for Magnetically Coupled Wireless Power Transfer. Electronics 2024, 13, 426. https://doi.org/10.3390/electronics13020426

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Fu Y, Zhu Y, Jiang D, Ji B, Peng Z. Improved Design of PCB Coil for Magnetically Coupled Wireless Power Transfer. Electronics. 2024; 13(2):426. https://doi.org/10.3390/electronics13020426

Chicago/Turabian Style

Fu, You, Yu Zhu, Dequan Jiang, Bing Ji, and Zhouhua Peng. 2024. "Improved Design of PCB Coil for Magnetically Coupled Wireless Power Transfer" Electronics 13, no. 2: 426. https://doi.org/10.3390/electronics13020426

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