HIGH-FREQUENCY WIRE AND COIL

Abstract

A high-frequency wire includes: a conductor portion which includes an inner layer formed of a material having lower conductivity than copper, and an outer layer which coats the inner layer and is formed of copper. In a frequency range of an AC current for using the high-frequency wire, in a case where a skin thickness δ [m] of a copper wire including a conductor portion formed of pure copper is defined as δ=√(2/ωσμ), a thickness t [m] of the outer layer satisfies 1.1δ

Description

TECHNICAL FIELD

The present invention relates to a high-frequency wire and a coil, for example, a high-frequency wire which is utilized in winding, a cable, and the like of various types of high-frequency equipment and a coil.

Priority is claimed on Japanese Patent Application No. 2013-249685, filed Dec. 2, 2013, the content of which is incorporated herein by reference.

BACKGROUND ART

In winding and cables of equipment conducting AC currents, an eddy current is generated inside a conductor by a magnetic field generated by the AC current. As a result thereof, there are cases where AC resistance increases due to a skin effect or proximity effect, thereby causing heat generation or an increase of electricity consumption.

As countermeasures for suppressing occurrence of the skin effect and the proximity effect, the diameter of an element wire is reduced and a litz wire in which each element wire is subjected to insulation coating is employed (for example, refer to PTL 1 to PTL 3).

However, even when the litz wire is employed, suppression of the occurrence of the skin effect and the proximity effect by reducing the diameter of an element wire has a limit. In addition, solving a problem in that an increase of resistance is easily caused by the proximity effect at a high frequency is not possible.

As countermeasures for reducing the proximity effect or the skin effect, which focuses on an element wire, for example, a method in which the surface of a copper wire is coated with silver having electrical conductivity higher than that of copper is included. The abovementioned method uses concentration of a current on the surface of the copper wire due to the skin effect. A wire material of which reduction of resistance is achieved by coating with silver, or a cable using the wire material is commercially available in the market. However, the reduction countermeasures have a drawback in that the cost is high.

In PTL 5, a coil using an element wire formed from a material having lower electrical conductivity than that of copper is proposed as a coil in which AC resistance can be reduced more than that of a copper wire. However, the coil allows reduction of the proximity effect, but resistance is increased. Thus, application of the coil is limited only to a case where the proximity effect is large.

In PTL 4, NPL 1, and NPL 2, a structure in which the copper wire is formed so as to cause a magnetic layer to be coated with the copper wire, and thereby application of a magnetic field into the copper wire is suppressed and the proximity effect is reduced is proposed. However, in this structure, a current is concentrated on the magnetic layer, and thus there is a problem in that the skin effect is increased at a high frequency.

PTL 6 discloses a copper-coated aluminium wire. However, in the copper-coated aluminium wire, reduction of AC resistance is difficult in comparison to a copper wire having the same wire diameter as the copper-coated aluminium wire.

PRIOR ART DOCUMENTS

Patent Documents

• [PTL 1] Japanese Unexamined Patent Application, First Publication No. 2009-129550
• [PTL 2] Japanese Unexamined Patent Application, First Publication No. S62-76216
• [PTL 3] Japanese Unexamined Patent Application, First Publication No. 2005-108654
• [PTL 4] PCT International Publication No. WO2006/046358
• [PTL 5] PCT International Publication No. WO2012/023378
• [PTL 6] Japanese Unexamined Patent Application, First Publication No. 2003-147583

Non-Patent Documents

• [NPL 1] MIZONO Tsutomu, and 7 others, “Reduction in Eddy Current Loss in Conductor Using Magnetoplated Wire”, Journal A of The Institute of Electrical Engineering, 2007, Volume No. 127, No. 10, p. 611-620
• [NPL 2] MIZONO Tsutomu, and 7 others, “Reduction of eddy current loss in magnetoplated wire”; The international Journal computation and mathematics in electrical and electronic engineering, 2009, Volume No. 28, No. 1, p. 57-66

DISCLOSURE OF INVENTION

Problem to be Solved by Invention

The present invention has been made in consideration of the above-referenced circumstances, and an object thereof is to provide a high-frequency wire and a coil in which the occurrence of the skin effect and the proximity effect can be suppressed and AC resistance can be reduced with low cost.

Means for Solving the Problems

The present inventor completed the present invention focusing on the fact that a lower limit value and an upper limit value of a frequency region in which AC resistance Rac due to the skin effect and the proximity effect is smaller than AC resistance Rac of a copper wire are determined so as to be associated with the skin thickness δ of the copper wire, which is set as a reference. That is, the present invention includes the following configurations.

According to a first aspect of the present invention, a high-frequency wire including a conductor portion is provided. The conductor portion includes an inner layer formed of a material having lower conductivity than copper, and an outer layer which coats the inner layer and is formed of copper. In a frequency range of an AC current for using the high-frequency wire, in a case where a skin thickness δ [m] of a copper wire including a conductor portion formed of pure copper is defined as δ=√(2/ωσμ), a thickness t [m] of the outer layer satisfies 1.1δ<t<2.7δ. Here, ω indicates an angular frequency of a current, which is represented by 2πf, μ indicates magnetic permeability [H/m] of the copper wire, σ indicates conductivity [Ω⁻¹m⁻¹] of copper, and f indicates a frequency [Hz].

The thickness t of the outer layer may satisfy 1.3δ<t<2.7δ.

The thickness t of the outer layer may satisfy 2.0δ<t<2.7δ.

An insulation coating layer may be provided on an outer circumferential surface of the conductor portion.

According to a second aspect of the present invention, a high-frequency coil including the high-frequency wire according to the first aspect is provided.

According to a third aspect of the present invention, a litz wire including a plurality of the twisted high-frequency wires according to the first aspect is provided.

According to a fourth aspect of the present invention, a cable including the litz wire according to the third aspect, which is subjected to insulation coating, is provided.

According to a fifth aspect of the present invention, a coil including the litz wire according to the third aspect or the cable according to the fourth aspect is provided.

Effects of the Invention

According to the aspects of the present invention, the thickness of the outer layer is in a predetermined range. Therefore, AC resistance thereof is lower than AC resistance of the copper wire. Accordingly, it is possible to improve a Q value of the coil.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a diagram illustrating a calculation example relating to resistance.

FIG. 2 is a diagram illustrating a calculation example relating to a proximity effect.

FIG. 3 is a diagram illustrating a calculation example relating to internal inductance.

FIG. 4 is a diagram illustrating a calculation example relating to the resistance.

FIG. 5 is a diagram illustrating a calculation example relating to the proximity effect.

FIG. 6 is a diagram illustrating a calculation example relating to the internal inductance.

FIG. 7A is a diagram illustrating a calculation example relating to the resistance, the proximity effect, and the internal inductance.

FIG. 7B is a diagram illustrating a calculation example relating to the resistance, the proximity effect, and the internal inductance.

FIG. 7C is a diagram illustrating a calculation example relating to the resistance, the proximity effect, and the internal inductance.

FIG. 8A is a diagram illustrating a calculation example relating to current density distribution.

FIG. 8B is a diagram illustrating a calculation example relating to current density distribution.

FIG. 8C is a diagram illustrating a calculation example relating to current density distribution.

FIG. 9A is a diagram illustrating a calculation example relating to eddy current density distribution.

FIG. 9B is a diagram illustrating a calculation example relating to eddy current density distribution.

FIG. 9C is a diagram illustrating a calculation example relating to eddy current density distribution.

FIG. 10A is a diagram illustrating a calculation example relating to a frequency region which causes resistance to be reduced in comparison to a copper wire.

FIG. 10B is a diagram illustrating a calculation example relating to a frequency region which causes the resistance to be reduced in comparison to the copper wire.

FIG. 10C is a diagram illustrating a calculation example relating to a frequency region which causes the resistance to be reduced in comparison to the copper wire.

FIG. 11A is a diagram illustrating a calculation example relating to a frequency region which causes the resistance and the proximity effect to be reduced in comparison to the copper wire.

FIG. 11B is a diagram illustrating a calculation example relating to a frequency region which causes the resistance and the proximity effect to be reduced in comparison to the copper wire.

FIG. 11C is a diagram illustrating a calculation example relating to a frequency region which causes the resistance and the proximity effect to be reduced in comparison to the copper wire.

FIG. 12A is a diagram illustrating a calculation example relating to a frequency region which causes the resistance and the proximity effect to be reduced in comparison to the copper wire, and causes internal inductance to be increased in comparison to the copper wire.

FIG. 12B is a diagram illustrating a calculation example relating to a frequency region which causes the resistance and the proximity effect to be reduced in comparison to the copper wire, and causes the internal inductance to be increased in comparison to the copper wire.

FIG. 12C is a diagram illustrating a calculation example relating to a frequency region which causes the resistance and the proximity effect to be reduced in comparison to the copper wire, and causes the internal inductance to be increased in comparison to the copper wire.

FIG. 13 is a diagram illustrating an analysis result.

FIG. 14 is a diagram illustrating an analysis result.

FIG. 15 is a diagram illustrating an analysis result.

FIG. 16A is a schematic diagram illustrating an analysis model of a high-frequency wire.

FIG. 16B is a schematic diagram illustrating an analysis model of the high-frequency wire.

FIG. 17 is a cross-sectional view illustrating a high-frequency wire according to an embodiment of the present invention.

FIG. 18 is a cross-sectional view illustrating a high-frequency wire including an insulation coating layer.

FIG. 19 is a perspective view illustrating an example of a litz wire.

FIG. 20 is a perspective view illustrating an example of a high-frequency coil.

FIG. 21 is a perspective view illustrating an example of a high-frequency coil.

FIG. 22 is a diagram illustrating a test result.

FIG. 23 is a diagram illustrating a test result.

EMBODIMENTS FOR CARRYING OUT THE INVENTION

<Structure of Wire>

FIG. 17 is a cross-sectional view illustrating a high-frequency wire 10 (referred to as a wire 10 below) according to an embodiment of the present invention.

The wire 10 illustrated herein is a wire used for a specific frequency band. The wire 10 includes a conductor portion 11. The conductor portion 11 is formed from a two-layer structure conductor in which an inner layer 1 and an outer layer 2 are included. The outer layer 2 is formed so as to cause an outer circumferential surface of the inner layer 1 to be coated with the outer layer 2.

The inner layer 1 is formed of a material (material having volume resistivity higher than copper) which has lower conductivity than copper. As the material of the inner layer 1, metal having lower conductivity than copper may be used. The material of the inner layer 1 may be an insulating body. The material of the inner layer 1 may be a magnetic material or a non-magnetic material. The inner layer 1 may have a cross-section shape which is circular.

The cross-section in the embodiment is referred to as a surface perpendicular to an axis direction of the conductor portion 11.

As the material of the inner layer 1, specifically, for example, an aluminium-containing material, an iron-containing material, a nickel-containing material, and the like are appropriate.

The inner layer 1 is desirably formed of a homogeneous material. The inner layer 1 may be formed of a composite material which is formed from a plurality of materials. However, in this case, conductivity (also referred to as electrical conductivity) may be obtained based on a cross-sectional area ratio of the plurality of materials.

As the aluminium-containing material, aluminium (Al) and aluminium alloys may be used. For example, aluminium for an electric use (EC aluminium), Al—Mg—Si-based alloys (within JIS 6000 to 6999), and the like may be used.

A two-layer structure conductor in which the inner layer is formed from an aluminium wire, and the outer layer is formed from copper is referred to as a copper-coating aluminium wire.

As the iron-containing material, iron (Fe) and iron alloys may be used. An example of the iron alloys includes a material containing one or more substances among carbon, silicon, nickel, tungsten, and chromium. For example, a steel wire, a stainless steel wire, or the like may be appropriately used as the inner layer 1.

A two-layer structure conductor in which the inner layer is formed from a steel wire, and the outer layer is formed from copper is referred to as a copper-coating steel wire.

As the nickel-containing material, nickel, nickel alloys, and the like may be used.

As the nickel alloys, a nickel-chromium alloy is exemplified. In this case, for example, a nichrome wire may be used as the inner layer 10.

A two-layer structure conductor in which the inner layer is formed from a nichrome wire, and the outer layer is formed from copper is referred to as a copper-coating nichrome wire.

The inner layer 1 is not limited to the exemplified materials. Pure metal such as magnesium, tungsten, titanium, and iron may be used for the inner layer 1. Copper alloys such as brass, phosphor bronze, silicon bronze, copper•beryllium alloys, and copper•nickel•silicon alloys may be used. In addition, an insulating body such as rubber and plastic may be used.

The outer layer 2 is formed of copper. It is desirable that the cross-section area of the outer layer 2 be equal to or less than 50% with respect to the cross-section area of the entirety of the conductor portion 11 obtained by combining the inner layer 1 and the outer layer 2. Such a cross-sectional area ratio (cross-sectional area ratio of the outer layer 2 to the cross-section area of the entirety of the conductor portion 11) may be set to be 5% to 50%, for example. The cross-sectional area ratio of the outer layer 2 is set to be in the above range, and thus the cross-sectional area ratio of the outer layer 2 contributes to reduction of AC resistance.

The outer layer 2 may have a constant thickness.

The diameter of the entirety of the wire 10 (diameter of the conductor portion 11) may be set to be 0.05 mm to 3.2 mm, for example.

In the high-frequency wire according to the embodiment, in addition to the inner layer and the outer layer, one or more insulating layers of resin, ethylene, or the like may be formed on an outer circumferential side of the outer layer.

Next, in order to describe a skin effect, electricity consumption in a case where an AC current is applied to the two-layer structure conductor is analyzed.

As illustrated in FIG. 16A, a two-layer structure conductor is modeled. In the two-layer structure conductor, the cross-section is circular, and layers are configured from materials different from each other, and are uniformly extended in a z-axis direction. An outer diameter of the i-th layer from the inside of the two-layer structure conductor is set as 2r_i, conductivity thereof is set as σ_i, and relative magnetic permeability thereof is set as μ_i. A time factor is set as e^jωt. μ₀ indicates magnetic permeability in a vacuum. i is a natural number. j indicates an imaginary unit, and ω indicates an angular frequency defined as ω=2πf when f is set to indicate a frequency.

As illustrated in FIG. 16B, when a current having amplitude of I flows in a z-axis direction of the lead wire, a z component E_z of an electric field satisfies the following wave equation.

$\begin{array}{cc}\frac{{\partial }^2E_z}{\partial r^{2}}+\frac{1}{r}\frac{\partial E_z}{\partial r}-j\omega {\mu }_i{\mu }_0{\sigma }_iE_z=0& \left(1\right)\end{array}$

Since Expression (1) is the 0-th order Bessel equation, Expression (1) has the following solution.

$\begin{array}{cc}{E}_z=\{\begin{array}{cc}{A}_1J_0\left(k_1r\right)& \left(r\le r_1\right)\\ A_2J_0\left(k_2r\right)+B_2Y_0\left(k_2r\right)& \left(r_1<r\le r_2\right)\end{array}& \left(2\right)\end{array}$

k_i² is represented by the following expression.

k _i ² =−jωμ ₀μ_iσ_i

J_n and Y_n are respectively set to be the n-th order Bessel function and the n-th order Neumann function. A_i and B_i are constants determined by the following boundary conditions.

${{E_z{|}_{r=\mathrm{ri}-}=E_z{|}_{r=\mathrm{ri}+}\frac{1}{{\mu }_i}\frac{\partial E_z}{\partial r}}_{r=\mathrm{ri}-}=\frac{1}{{\mu }_{i+1}}\frac{\partial E_z}{\partial r}}_{r=\mathrm{ri}+}$

A magnetic field is represented by the following expression, based on the Maxwell equation. The magnetic field H_θ indicates a component of a θ direction.

$\begin{array}{cc}{H}_{\theta }=\{\begin{array}{cc}-\frac{{\sigma }_1}{k_1}A_1J_0\left(k_1r\right)& \left(r\le r_1\right)\\ -\frac{{\sigma }_2}{k_2}\left[A_2J_0\left(k_2r\right)+B_2Y_0\left(k_2r\right)\right]& \left(r_1<r\le r_2\right)\end{array}& \left(3\right)\end{array}$

A time average of electricity consumption of the lead wire having a length l is equal to a value obtained by integrating a pointing vector flowing from the surface of the lead wire, with the surface S of the lead wire. Thus, the time average is represented as follows.

$\begin{array}{cc}\begin{array}{c}{\stackrel{\_}{P}}_s=-\frac{1}{2}\oint E\times H^{*}·S\\ =\frac{j\omega {\mu }_N{\mu }_0l{I}^2}{4\pi \xi }·\frac{A_NJ_0\left(\xi \right)+B_NY_0\left(\xi \right)}{A_NJ_0^{\prime }\left(\xi \right)+B_NY_0^{\prime }\left(\xi \right)}\\ =\frac{1}{2}{I}^2\left(R_s+j\omega L_i\right)l\end{array}& \left(4\right)\end{array}$

(P_s: time average L_i:internal inductance of unit length of conductor)

ζ is indicated by ζ=k₂r₂.

Resistance R_s and internal inductance L_i when an AC current is applied to the two-layer structure conductor having a unit length are represented by the following expression.

It is desirable that the frequency of the AC current be a frequency in a specific frequency region which is defined (set) as a range in which the wire (product) is used.

$\begin{array}{cc}{R}_s=\mathrm{Re}\left[\frac{j\omega {\mu }_2{\mu }_0}{2\pi \xi }\frac{A_2J_0\left(\xi \right)+B_2Y_0\left(\xi \right)}{A_2J_0^{\prime }\left(\xi \right)+B_2Y_0^{\prime }\left(\xi \right)}\right]L_i=\mathrm{Im}\left[\frac{j{\mu }_2{\mu }_0}{2\pi \xi }\frac{A_2J_0\left(\xi \right)+B_2Y_0\left(\xi \right)}{A_2J_0^{\prime }\left(\xi \right)+B_2Y_0^{\prime }\left(\xi \right)}\right]& \left(5\right)\end{array}$

When σ₁=σ₂ and μ₁=μ₂, A₂=1 and B₂=0 are set and R_s in Expression (5) is represented by the following expression.

$\begin{array}{cc}{R}_s=\mathrm{Re}\left[\frac{j{\mathrm{\omega \mu }}_2{\mu }_0}{2\pi \xi }\frac{J_0\left(\xi \right)}{J_0^{\prime }\left(\xi \right)}\right]& \left(6\right)\end{array}$

The layers are magnetic substances. In a case where magnetic loss is indicated by magnetic hysteresis and the like, the loss may be indicated by introducing an imaginary part into magnetic permeability. For example, the following expression is established.

μ₁=μ_1r+μ_1i  (7)

Next, in order to describe a proximity effect, electricity consumption in a case where an AC magnetic field is uniformly applied to the two-layer structure conductor from the outside is analyzed.

As illustrated in FIG. 16A, if a vector potential satisfying H=∇×A is introduced, the vector potential A₂=H₀r sin θ in the z-axis direction is applied to a magnetic field having uniform amplitude H₀ from an x-axis direction.

When the magnetic field is caused to react with the lead wire, A_z satisfies the following wave equation.

$\begin{array}{cc}\frac{{\partial }^2A_z}{\partial r^2}+\frac{1}{r}\frac{\partial A_z}{\partial r}+\frac{1}{r}\frac{{\partial }^2A_z}{\partial {\theta }^2}+k_2^2A_z=0& \left(8\right)\end{array}$

Expression (8) has the following solution.

$\begin{array}{cc}{A}_z=\sin \theta \times \{\begin{array}{cc}{C}_1J_1\left(k_1r\right)& \left(r\le r_1\right)\\ C_2J_1\left(k_2r\right)+D_2Y_1\left(k_2r\right)& \left(r_1<r\le r_2\right)\\ C_3r+D_3r^{-1}& \left(r_2\le r\right)\end{array}& \left(9\right)\end{array}$

C_i and D_i are constants determined by the following boundary conditions.

${{{\mu }_iA_z{|}_{r=\mathrm{ri}-}={\mu }_{i+1}A_z{|}_{r=\mathrm{ri}+}\frac{\partial A_z}{\partial r}}_{r=\mathrm{ri}-}=\frac{\partial A_z}{\partial r}}_{r=\mathrm{ri}+}$

The magnetic field and the electric field are represented by the following expression by using Expression (9).

$\begin{array}{cc}{H}_{\theta }=\{\begin{array}{cc}-k_1\left[C_1J_1^{\prime }\left(k_1r\right)\right]\sin \theta & \left(r\le r_1\right)\\ -k_2\left[C_2J_1^{\prime }\left(k_2r\right)+D_2Y_1^{\prime }\left(k_2r\right)\right]\sin \theta & \left(r_1<r\le r_2\right)\\ \left[C_3-\frac{D_3}{r^2}\right]\sin \theta & \left(r_2<r_2\right)\end{array}& \left(10\right)\\ E_z=\{\begin{array}{cc}\frac{k_1^2}{{\sigma }_{1}}\left[C_1J_1^{\prime }\left(k_1r\right)\right]\sin \theta & \left(r\le r_1\right)\\ \frac{k_2^2}{{\sigma }_{1}}\left[C_2J_1^{\prime }\left(k_2r\right)+D_2Y_1^{\prime }\left(k_2r\right)\right]\sin \theta & \left(r_1<r\le r_2\right)\\ \frac{D_3}{j\omega {\mu }_0r^3}\sin \theta & \left(r_2<r_2\right)\end{array}& \left(11\right)\end{array}$

At this time, since electricity consumption in the lead wire is equal to a real part of a value obtained by integrating a pointing vector flowing from the surface of the lead wire, with the surface S of the lead wire, when the magnetic field having amplitude H₀ is caused to react, the time average of eddy current loss occurring in the lead wire having a length l is represented by the following expression.

$\begin{array}{cc}\begin{array}{c}{\stackrel{\_}{P}}_p=-\frac{1}{2}\oint E\times H^{*}·S\\ =-\frac{2\pi l{\xi }^2{H_0}^2}{{\sigma }_N}\frac{\xi {\mathrm{XY}}^{*}}{\lambda {Z}^{2}}\\ =\frac{1}{2}{I}^2\left(R_p+j\omega L_m\right)l\end{array}& \left(12\right)\\ X=C_2J_1\left(\xi \right)+D_2Y_1\left(\xi \right)Y=C_2J_1^{\prime }\left(\xi \right)+D_2Y_1^{\prime }\left(\xi \right)Z=\left({\mu }_2-1\right)X+\xi \left[C_2J_0\left(\xi \right)+D_2Y_0\left(\xi \right)\right]& \end{array}$

(P_p:time average L_m:mutual internal inductance of unit length of conductor)

Since a near magnetic field of a coil is generated by a current I flowing in the coil, the amplitude H₀ of the magnetic field is proportional to the amplitude of I. If the proportional coefficient is set as α, H₀ is represented as follows.

|H₀|=α|I|  (13)

Thus, resistance R_p by the proximity effect is represented as follows.

R _p=α²D_p  (14)

D_p is represented as follows.

$\begin{array}{cc}{D}_p=-\frac{4\pi {\xi }^2}{{\sigma }_{2}}\mathrm{Re}\left[\frac{\xi {\mathrm{XY}}^{*}}{{Z}^2}\right]& \left(15\right)\end{array}$

When σ₁=σ₂ and μ₁=μ₂ are set, C₂=1 and D₂=0 are set, and Expression (15) is represented by the following expression.

$\begin{array}{cc}{D}_p=-\frac{4\pi }{{\sigma }_{2}}\mathrm{Re}\left[\frac{\xi J_1\left(\xi \right)J_1^{\prime }\left(\xi \right)}{{J_0\left(\xi \right)}^2}\right]& \left(16\right)\end{array}$

AC resistance R_ac of the coil or the cable is represented as the sum of resistance R_s by electrification and resistance R_p by the proximity effect.

R _ac =R _s +R _p  (17)

In this manner, R_s and D_p are formulated, and thus a lead wire which is a two-layer structure conductor of which the outer layer is configured by copper, and a lead wire (copper wire) formed from copper are compared to each other regarding the skin effect and the proximity effect.

EXAMPLES

Examples 1 to 3, Comparative Example 1

Regarding a two-layer structure conductor (copper-coating aluminium wire (Example 1), a two-layer structure conductor (copper-coating steel wire) (Example 2), and a two-layer structure conductor (copper-coating nichrome wire) (Example 3), the following calculation was performed. In the copper-coating aluminium wire (Example 1), the inner layer was formed by an alloy aluminium wire, and the outer layer was formed by copper. In the copper-coating steel wire (Example 2), the inner layer was formed by a steel wire and the outer layer was formed by copper. In the copper-coating nichrome wire (Example 3), the inner layer was formed by a nickel wire, and the outer layer was formed by copper.

For comparison, similar calculation was performed on a copper wire having a single-layer structure (one-layer structure) (Comparative Example 1). The copper wire may have a cross-section which is circular. The single-layer structure is referred to as a structure formed from a homogeneous material.

In the following descriptions, the two-layer structure conductor or the copper wire may be singly referred to as a “lead wire”. In addition, alloy aluminium may be singly referred to as “aluminium”.

The outer diameter of the lead wires (Examples 1 to 3 and Comparative Example 1) was set to 1.0 mm. In Examples 1 to 3 (two-layer structure conductors), the cross-sectional area ratio of the outer layer to the entirety of the lead wire was set to 25%.

Regarding the two-layer structure conductors in Examples 1 to 3 and Comparative Example 1, resistance R_s and internal inductance L_i shown in the abovementioned Expression (5) were obtained by calculation. D_p shown in the abovementioned Expression (15) was obtained by calculation.

With the calculation, volume resistivity (20° C.) of copper was set to 1.72×10⁻⁸ [Ω·m], volume resistivity (20° C.) of alloy aluminium was set to 3.02×10⁻⁸ [Ω·m], volume resistivity (20° C.) of steel was set to 1.57×10⁻⁷ [Ω·m], and volume resistivity (20° C.) of nichrome was set to 1.50×10⁻⁶ [Ω·m]. The volume resistivity of alloy aluminium referred to an I-aluminium alloy wire (JEC-3405, standard of Electrical Standards Committee in Institute of Electrical Engineering). The conductivity (20° C.) of copper was set to 5.8×10⁷ [Ω⁻¹·m⁻¹], the conductivity (20° C.) of alloy aluminium was set to 3.3×10⁷ [Ω⁻¹·m⁻¹], the conductivity (20° C.) of steel was set to 6.4×10⁶ [Ω⁻¹·m⁻¹], and the conductivity (20° C.) of nichrome was set to 6.6×10⁶ [Ω⁻¹·m⁻¹].

Relative magnetic permeability of copper was set to 1, the relative magnetic permeability of alloy aluminium was set to 1, the relative magnetic permeability of steel was set to 100, and the relative magnetic permeability of nichrome was set to 1.

FIG. 1 illustrates a calculation result of the resistance R_s. The resistance R_s in Examples 1 to 3 (two-layer structure conductors) was lower than that in Comparative Example 1 (copper wire), in a range in which a frequency was higher than a first frequency (about 1.2 MHz) and less than a second frequency (about 7.1 MHz) which was higher than the first frequency.

That is, the resistance R_s in Examples 1 to 3 (two-layer structure conductors) was higher than the resistance R_s in Comparative Example 1 (copper wire) on a lower frequency side than the first frequency. The resistance R_s in Examples 1 to 3 and the resistance R_s in Comparative Example 1 matched each other at the first frequency. The resistance R_s in Examples 1 to 3 was lower than the resistance R_s in Comparative Example 1, in a range in which a frequency was on a higher frequency side than the first frequency and was less than the second frequency. The resistance R_s in Examples 1 to 3 and the resistance R_s in Comparative Example 1 matched each other again at the second frequency. The resistance R_s in Examples 1 to 3 was higher than the resistance R_s in Comparative Example 1, on a higher frequency side than the second frequency.

FIG. 2 illustrates a calculation result of D_p. D_p in Examples 1 to 3 (two-layer structure conductors) was lower than D_p in Comparative Example 1 (copper wire), in a range in which a frequency was higher than a first frequency (about 1.5 MHz) and less than a second frequency (about 7.1 MHz) which was higher than the first frequency.

That is, D_p in Examples 1 to 3 (two-layer structure conductors) was higher than D_p in Comparative Example 1 (copper wire) on a lower frequency side than the first frequency. D_p in Examples 1 to 3 and D_p in Comparative Example 1 matched each other at the first frequency. D_p in Examples 1 to 3 was lower than D_p in Comparative Example 1, in a range in which a frequency was on a higher frequency side than the first frequency and was less than the second frequency. D_p in Examples 1 to 3 and D_p in Comparative Example 1 matched each other again at the second frequency. D_p in Examples 1 to 3 was higher than D_p in Comparative Example 1, on a higher frequency side than the second frequency.

FIG. 3 illustrates a calculation result of the internal inductance L_i. L_i in Examples 1 to 3 (two-layer structure conductors) was higher than L_i in Comparative Example 1 (copper wire), in a range in which a frequency was on a higher frequency than a first frequency (about 3.6 MHz) and less than a second frequency (about 10 MHz) which was higher than the first frequency.

That is, the internal inductance L_i in Examples 1 to 3 (two-layer structure conductors) was lower than L_i in Comparative Example 1 (copper wire) on a lower frequency side than the first frequency. L_i in Examples 1 to 3 and L_i in Comparative Example 1 matched each other at the first frequency. L_i in Examples 1 to 3 was higher than L_i in Comparative Example 1, in a range in which a frequency was on the higher frequency side than the first frequency and was less than the second frequency. L_i in Examples 1 to 3 and L_i in Comparative Example 1 matched each other again at the second frequency. L_i in Examples 1 to 3 was lower than L_i in Comparative Example 1, on a higher frequency side than the second frequency.

FIG. 4 is a diagram illustrating a ratio (Examples 1 to 3/Comparative Example 1) of the resistance R_s between Examples 1 to 3 and Comparative Example 1 (copper wire), for easy understanding of the calculation result illustrated in FIG. 1. The following are understood based on FIG. 4.

In Example 1 (copper-coating aluminium wire), the resistance R_s could be reduced by about 1%, which was the maximum, in comparison to Comparative Example 1 (copper wire).

In Example 2 (copper-coating steel wire), the resistance R_s could be reduced by approximately 7%, which was the maximum, in comparison to Comparative Example 1 (copper wire).

In Example 3 (copper-coating nichrome wire), the resistance R_s could be reduced by approximately 7%, which was the maximum, in comparison to Comparative Example 1 (copper wire).

FIG. 5 is a diagram illustrating a ratio (Examples 1 to 3/Comparative Example 1) of D_p between Examples 1 to 3 and Comparative Example 1 (copper wire), for easy understanding of the calculation result illustrated in FIG. 2. The following are understood based on FIG. 5.

In Example 1 (copper-coating aluminium wire), D_p could be reduced by about 1%, which was the maximum, in comparison to Comparative Example 1 (copper wire).

In Example 2 (copper-coating steel wire), D_p could be reduced by approximately 7%, which was the maximum, in comparison to Comparative Example 1 (copper wire).

In Example 3 (copper-coating nichrome wire), D_p could be reduced by approximately 7%, which was the maximum, in comparison to Comparative Example 1 (copper wire).

FIG. 6 is a diagram illustrating a ratio (Examples 1 to 3/Comparative Example 1) of the internal inductance L_i between Examples 1 to 3 and Comparative Example 1 (copper wire), for easy understanding of the calculation result illustrated in FIG. 3. The following are understood based on FIG. 6.

In Example 1 (copper-coating aluminium wire), the internal inductance L_i could be increased by approximately 0.3%, which was the maximum, in comparison to Comparative Example 1 (copper wire).

In Example 2 (copper-coating steel wire), the internal inductance L_i could be increased by approximately 2%, which was the maximum, in comparison to Comparative Example 1 (copper wire).

In Example 3 (copper-coating steel wire), the internal inductance L_i could be increased by approximately 2%, which was the maximum, in comparison to Comparative Example 1 (copper wire).

Example 4

A two-layer structure conductor (copper-coating steel wire) was similar to that in Example 2 except that the cross-sectional area ratio of the outer layer was set to 75%. Regarding the two-layer structure conductor (copper-coating steel wire), the ratio of R_s, the ratio of D_p, and the ratio of L_i to R_s, D_p, and L_i in Comparative Example 1 (copper wire) were obtained. FIG. 7A illustrates a result.

In FIG. 7A, the ratio of R_s to R_s in Comparative Example 1 (copper wire) was marked as “R_s (75% CS/Cu)”, the ratio of D_p to D_p in Comparative Example 1 (copper wire) was marked as “D_p (75% CS/Cu)”, and the ratio of L_i to L_i in Comparative Example 1 (copper wire) was marked as (“L_i (75% CS/Cu)”.

Regarding Example 2, the ratio of R_s, the ratio of D_p, and the ratio of L_i to R_s, D_p, and L_i in Comparative Example 1 (copper wire) were also obtained. FIG. 7A illustrates a result.

In FIG. 7A, the ratio of R_s to R_s in Comparative Example 1 (copper wire) was marked as “R_s (25% CS/Cu)”, the ratio of D_p to D_p in Comparative Example 1 (copper wire) was marked as “D_p (25% CS/Cu)”, and the ratio of L_i to L_i in in Comparative Example 1 (copper wire) was marked as “L_i (25% CS/Cu)”.

Example 5

A two-layer structure conductor (copper-coating steel wire) was similar to that in Example 2 except that the cross-sectional area ratio of the outer layer was set to 5%. Regarding the two-layer structure conductor (copper-coating steel wire), the ratio of R_s, the ratio of D_p, and the ratio of L_i to R_s, D_p, and L_i in Comparative Example 1 (copper wire) were obtained. FIG. 7A illustrates a result.

In FIG. 7A, the ratio of R_s to R_s in Comparative Example 1 (copper wire) was marked as “R_s (5% CS/Cu)”, the ratio of D_p to D_p in Comparative Example 1 (copper wire) was marked as “D_p (5% CS/Cu)”, and the ratio of L_i to L_i in Comparative Example 1 (copper wire) was marked as “L_i (5% CS/Cu)”.

As illustrated in FIG. 7A, R_s in Example 4 (copper-coating steel wire) is smaller than R_s in Comparative Example 1 (copper wire), in a frequency region A1. For this reason, Example 4 has an advantage of R_s over Comparative Example 1 in the frequency region A1.

Since D_p in Example 4 is smaller than D_p in Comparative Example 1 in the frequency region A1, Example 4 has an advantage of D_p over Comparative Example 1 in the frequency region A1.

In a frequency region B1, which is a region in the frequency region A1 and is narrower than the frequency region A1, since L_i in Example 4 is greater than L_i in Comparative Example 1, Example 4 has an advantage of L_i over Comparative Example 1 in the frequency region A1.

As described above, Example 4 has advantages of R_s and D_p in the frequency region A1, and also has an advantage of L_i in the frequency region B1, which is narrower than the region A1.

As illustrated in FIG. 7B, Example 2 has advantages of R_s and D_p in a frequency region A2, and also has an advantage of L_i in a frequency region B2, which is narrower than the region A2.

As illustrated in FIG. 7C, Example 5 has advantages of R_s and D_p in a frequency region A3, and also has an advantage of L_i in a frequency region B3, which is narrower than the region A3.

The result of R_s, D_p, and L_i may be considered as follows.

FIGS. 8A to 8C are diagrams illustrating a real part of current density distribution in a radial direction of a copper-coating nichrome wire when a current having a frequency of 1 kHz (FIG. 8A), 3 MHz (FIG. 8B), or 10 MHz (FIG. 8C) flows into the copper-coating nichrome wire (Example 3, cross-sectional area ratio of outer layer: 25%, outer diameter: 1.0 mm).

The current density distribution for Comparative Example 1 (copper wire) was similarly calculated.

The current density distribution was calculated by multiplying conductivity by Expression (2).

In FIG. 8A, the current uniformly flows in a positive direction, at 1 kHz, and most of the current flows only into the outer layer (copper) of the copper-coating nichrome wire. For this reason, it is understood that the effective cross-section area in which the current flows in the copper-coating nichrome wire is smaller than that in the copper wire, and the current distribution has large deviation.

Since the loss has a square function of a current, the loss is increased as the deviation of the current distribution becomes larger. For this reason, the copper-coating nichrome wire has larger resistance than the copper wire.

In FIG. 8B, it is understood that a portion of the current flowing the copper wire flows into the inside thereof in a negative direction (that is, reflux is caused) at 3 MHz, but, in the copper-coating nichrome wire, the reflux is not caused.

Since the reflux is caused in the copper wire, the current in the positive direction is largely deviated, and thus the resistance is larger than that of the copper-coating nichrome wire.

In FIG. 8C, the reflux is also caused in the outer layer of a copper-nichrome wire, at 10 MHz. The current density distribution of the copper-nichrome wire is approximate to the current density distribution of the copper wire.

It is understood that the reflux is caused in the copper wire in a frequency region including 3 MHz, and the current is concentrated on a portion corresponding to the outer layer, and thus the loss in the copper-nichrome wire is smaller than the loss in the copper wire, based on the results.

As described above, in the two-layer structure conductor in which the inner layer is formed from a material having lower conductivity than copper, and the outer layer is formed from copper, it is possible to suppress an increase of resistance in a specific frequency region, in comparison to that of the copper wire. Accordingly, it is possible to improve the Q value of a coil.

FIGS. 9A to 9C are diagrams illustrating an absolute value of eddy current density on a surface which is perpendicular to an external magnetic field and passes through the center of a lead wire (copper-coating nichrome wire) when a uniform magnetic field is applied to the copper-coating nichrome wire (Example 3, cross-sectional area ratio of outer layer: 25%, outer diameter: 1.0 mm) from the outside thereof.

FIG. 9A illustrates an absolute value of eddy current density in a case where the frequency of the magnetic field is 500 kHz. FIG. 9B illustrates an absolute value of eddy current density in a case where the frequency of the magnetic field is 2 MHz. FIG. 9C illustrates an absolute value of eddy current density in a case where the frequency of the magnetic field is 10 MHz.

The absolute value of the eddy current density for Comparative Example 1 (copper wire) was similarly calculated.

The current density distribution was calculated by multiplying conductivity by Expression (11).

In FIG. 9A, it is understood that an eddy current in the copper-coating nichrome wire flows into the outer layer at 500 kHz, and thus the current density distribution in the copper-coating nichrome wire is deviated larger than that of the copper wire.

In FIG. 9B, it is understood that the current density of the copper wire on the surface of the lead wire is denser than that of the copper-coating nichrome wire, at 2 MHz, and thus the current density distribution in the copper wire is deviated larger than that in the copper-coating nichrome wire.

In FIG. 9C, it is understood that the current density distribution of the copper-nichrome wire is approximate to the current density distribution of the copper wire at 10 MHz.

It is understood that deviation of the eddy current in the copper wire is larger than deviation of the eddy current in the copper-coating nichrome wire in a frequency region including 2 MHz, and thus the loss in the copper-nichrome wire is smaller than the loss in the copper wire, based on the results.

As described above, in the two-layer structure conductor in which the outer layer is formed from copper and the inner layer is configured by a material having lower conductivity than copper (material having high volume resistivity), it is possible to suppress an increase of eddy current loss in a specific frequency region, in comparison to that of the copper wire.

Examples 6 to 8

In a copper-coating aluminium wire (Example 6), a copper-coating steel wire (Example 7), and a copper-coating nichrome wire (Example 8) which were two-layer structure conductors having an outer diameter of 0.1 mm, 1.0 mm, or 3.2 mm, a frequency region in which the resistance R_s was smaller than the resistance R_s of the copper wire was obtained by simulation.

The cross-sectional area ratio of the outer layer was set to 5%, 15%, 25%, and 50%.

FIGS. 10A to 10C illustrate the lower limit value and the upper limit value of the obtained frequency region.

FIGS. 10A to 10C respectively illustrate results of cases where the outer diameter is 0.1 mm, 1.0 mm, and 3.2 mm.

As illustrated in FIGS. 10A to 10C, if the cross-sectional area ratio of the outer layer (copper) is changed, the frequency region in which R_s of the two-layer structure conductor is smaller than R_s of the copper wire is changed. For this reason, it is possible to reduce the resistance of the two-layer structure conductor in comparison to that of the copper wire in a wide frequency region by adjusting the cross-sectional area ratio of the outer layer (copper). Accordingly, it is possible to improve the Q value of a coil.

In the copper-coating aluminium wire (Example 6), the copper-coating steel wire (Example 7), and the copper-coating nichrome wire (Example 8), a frequency region in which the resistance R_s was smaller than the resistance R_s of the copper wire and D_p was smaller than D_p of the copper wire was obtained by simulation.

FIGS. 11A to 11C illustrate the lower limit value and the upper limit value of the obtained frequency region.

FIGS. 11A to 11C respectively illustrate results of cases where the outer diameter is 0.1 mm, 1.0 mm, and 3.2 mm.

As illustrated in FIGS. 11A to 11C, if the cross-sectional area ratio of the outer layer (copper) is changed, the frequency region in which the resistance R_s of the two-layer structure conductor is smaller than the resistance R_s of the copper wire and D_p of the two-layer structure conductor is smaller than D_p of the copper wire is changed. For this reason, it is possible to reduce the resistance and the proximity effect of the two-layer structure conductor in comparison to those of the copper wire in a wide frequency region by adjusting the cross-sectional area ratio of the outer layer (copper). Accordingly, it is possible to improve the Q value of a coil.

In the copper-coating aluminium wire (Example 6), the copper-coating steel wire (Example 7), and the copper-coating nichrome wire (Example 8), a frequency region in which R_s was smaller than R_s of the copper wire and D_p was smaller than D_p of the copper wire, but the internal inductance L_i was larger than the internal inductance L_i of the copper wire was obtained by simulation.

FIGS. 12A to 12C illustrate the lower limit value and the upper limit value of the obtained frequency region.

FIGS. 12A to 12C respectively illustrate results of cases where the outer diameter is 0.1 mm, 1.0 mm, and 3.2 mm.

As illustrated in FIGS. 12A to 12C, if the cross-sectional area ratio of the outer layer (copper) is changed, the frequency region in which R_s is smaller than R_s of the copper wire and D_p is smaller than D_p of the copper wire, but L_i is larger than L_i of the copper wire is changed.

For this reason, it is possible to reduce the resistance and the proximity effect of the two-layer structure conductor and to increase the internal inductance of the two-layer structure conductor, in comparison to those of the copper wire in a wide frequency region by adjusting the cross-sectional area ratio of the outer layer (copper).

Accordingly, it is possible to improve the Q value of a coil.

Table 1 to Table 3 show (1) the lower limit value and the upper limit value of a frequency region in which the resistance R_s is smaller than the resistance R_s of the copper wire, (2) the lower limit value and the upper limit value of a frequency region in which R_s is smaller than R_s of the copper wire and D_p is smaller than D_p of the copper wire, and (3) the lower limit value and the upper limit value of a frequency region in which R_s is smaller than R_s of the copper wire and D_p is smaller than D_p of the copper wire, but the internal inductance L_i is larger than the internal inductance L_i of the copper wire, regarding the copper-coating aluminium wire (Example 6), the copper-coating steel wire (Example 7), and the copper-coating nichrome wire (Example 8).

TABLE 1
		Wire diameter
		0.1 mmφ
		Wire type
		Copper-coating	Copper-coating	Copper-coating
		aluminium wire	steel wire	nichrome wire
		Lower	Upper	Lower	Upper	Lower	Upper
		limit	limit	limit	limit	limit	limit
	Cover-	fre-	fre-	fre-	fre-	fre-	fre-
	age of	quency	quency	quency	quency	quency	quency
	copper	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]
Only Rs	0.5	19600	137000	27300	152000	26500	148000
	0.25	126000	665000	127000	724000	119000	712000
	0.15	385000	1960000	375000	2130000	355000	2110000
	0.05	3740000	20500000	3560000	20600000	3550000	20500000
Rs and Dp	0.5	33600	137000	35000	152000	42400	148000
	0.25	143000	665000	142000	724000	153000	712000
	0.15	411000	1960000	402000	2130000	407000	2110000
	0.05	3820000	20500000	3640000	20600000	3640000	20500000
Rs, Dp,	0.5	75200	137000	79700	152000	77700	148000
and Li	0.25	369000	665000	377000	724000	364000	712000
	0.15	1090000	1960000	1100000	2130000	1090000	2110000
	0.05	10600000	20500000	10600000	20600000	10600000	20500000
			Wire diameter
			0.4 mmφ
			Wire type
			Copper-coating	Copper-coating	Copper-coating
			aluminium wire	steel wire	nichrome wire
			Lower	Upper	Lower	Upper	Lower	Upper
			limit	limit	limit	limit	limit	limit
		Cover-	fre-	fre-	fre-	fre-	fre-	fre-
		age of	quency	quency	quency	quency	quency	quency
		copper	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]
	Only Rs	0.5	1220	8590	1700	9500	1650	9290
		0.25	7970	41600	8000	45200	7510	44500
		0.15	24000	123000	23400	133000	22100	132000
		0.05	233000	1280000	222000	1280000	221000	1280000
	Rs and Dp	0.5	2100	8590	2180	9500	2650	9290
		0.25	8990	41600	8980	45200	9630	44500
		0.15	25600	123000	25100	133000	25400	132000
		0.05	238000	1280000	227000	1280000	227000	1280000
	Rs, Dp,	0.5	4700	8590	4980	9500	4850	9290
	and Li	0.25	23000	41600	23500	45200	22700	44500
		0.15	68700	123000	69500	133000	68600	132000
		0.05	658000	1280000	660000	1280000	657000	1280000

	TABLE 2
	Wire diameter
	1.0 mmφ	1.8 mmφ
	Wire type
	Copper-coating	Copper-coating	Copper-coating	Copper-coating	Copper-coating	Copper-coating
	aluminium wire	steel wire	nichrome wire	aluminium wire	steel wire	nichrome wire
		Lower	Upper	Lower	Upper	Lower	Upper	Lower	Upper	Lower	Upper	Lower	Upper
		limit	limit	limit	limit	limit	limit	limit	limit	limit	limit	limit	limit
	Cover-	fre-	fre-	fre-	fre-	fre-	fre-	fre-	fre-	fre-	fre-	fre-	fre-
	age of	quency	quency	quency	quency	quency	quency	quency	quency	quency	quency	quency	quency
	copper	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]	[kHz]
Only Rs	0.5	196	1380	216	1450	265	1480	60.8	424	84.4	469	82	459
	0.25	1260	6660	1260	6650	1190	7120	393	2050	394	2230	370	2190
	0.15	3850	19700	3740	20800	3550	21100	1180	6070	1150	6580	1090	6530
	0.05	37400	188000	37400	187000	35500	201000	11500	57900	11100	62300	10900	62300
Rs and Dp	0.5	336	1380	385	1450	424	1480	103	424	107	469	130	459
	0.25	1430	6660	1430	6650	1530	7120	443	2050	443	2230	475	2190
	0.15	4110	19700	4020	20800	4070	21100	1260	6070	1230	6580	1240	6530
	0.05	38200	188000	38200	187000	36400	201000	11700	57900	11300	62300	11100	62300
Rs, Dp,	0.5	752	1380	726	1450	777	1480	231	424	245	469	239	459
and Li	0.25	3690	6660	3690	6650	3640	7120	1130	2050	1150	2230	1110	2190
	0.15	10900	19700	10800	20800	10900	21100	3390	6070	3420	6580	3380	6530
	0.05	104000	188000	104000	187000	104000	201000	32400	57900	34500	62300	32400	62300

	TABLE 3
	Wire diameter
	2.5 mmφ	3.2 mmφ
	Wire type
	Copper-coating	Copper-coating	Copper-coating	Copper-coating	Copper-coating	Copper-coating
	aluminium wire	steel wire	nichrome wire	aluminium wire	steel wire	nichrome wire
		Lower	Upper	Lower	Upper	Lower	Upper	Lower	Upper	Lower	Upper	Lower	Upper
		limit	limit	limit	limit	limit	limit	limit	limit	limit	limit	limit	limit
	Cover-	fre-	fre-	fre-	fre-	fre-	fre-	fre-	fre-	fre-	fre-	fre-	fre-
	age of	quency	quency	quency	quency	quency	quency	quency	quency	quency	quency	quency	quency
	copper	|kHz|	|kHz|	|kHz|	|kHz|	|kHz|	|kHz|	|kHz|	|kHz|	|kHz|	|kHz|	|kHz|	|kHz|
Only Rs	0.5	31.4	220	43.7	243	42.4	237	19.1	134	26.6	148	25.8	145
	0.25	203	1060	204	1150	191	1140	123	650	124	707	116	696
	0.15	618	3150	601	3410	569	3380	376	1920	366	2080	347	2060
	0.05	6000	30000	5710	32300	5690	32300	3660	18300	3480	19700	3470	19700
Rs and Dp	0.5	53.9	220	56.1	243	68	237	32.8	134	34.2	148	41.4	145
	0.25	229	1060	229	1150	245	1140	139	650	139	707	149	696
	0.15	659	3150	644	3410	652	3380	402	1920	392	2080	397	2060
	0.05	6120	30000	5830	32300	5830	32300	3730	18300	3560	19700	3550	19700
Rs, Dp,	0.5	119	220	126	243	123	237	73.5	134	77.8	148	75.9	145
and Li	0.25	592	1060	604	1150	583	1140	361	650	368	707	355	696
	0.15	1750	3150	1770	3410	1750	3380	1060	1920	1070	2080	1060	2060
	0.05	16700	30000	16800	32300	16700	32300	10200	18300	11000	19700	10100	19700

The reason that R_s, D_p, and L_i of the two-layer structure conductor are different from R_s, D_p, and L_i of the copper wire is because flowing of the current into the inner layer having low conductivity is difficult, and thus the current distribution by the skin effect is different between the two-layer structure conductor and the copper wire.

The lower limit frequency and the upper limit frequency of the above-described frequency region may be determined in association with the skin thickness δ [m] in a copper wire which functions as a reference.

The “copper wire which functions as a reference” includes a conductor portion formed from pure copper (formed only by pure copper). It is preferable that the copper wire have a wire diameter the same as that of the two-layer structure conductor. However, the copper wire may have a different wire diameter.

FIG. 13 illustrates a correlation between a ratio of the skin thickness δ of the copper wire and the radius r₂ of the two-layer structure conductor, and a ratio of the thickness t of the outer layer (copper) in the two-layer structure conductor and the radius r₂ of the two-layer structure conductor, at the lower limit frequency and the upper limit frequency of a frequency region in which R_s of the two-layer structure conductor is smaller than R_s of the copper wire.

Regression analysis was performed on the results by using a linear function, thereby a regression analysis straight line illustrated in FIG. 13 was obtained. The solid line indicates a regression analysis straight line for the lower limit frequency, and the broken line indicates a regression analysis straight line of the upper limit frequency.

The skin thickness δ [m] of the copper wire is represented by the following Expression (18).

δ=√(2/ωσμ)  (18)

(ω: angular frequency (=2πf) of current, μ: magnetic permeability [H/m] of copper wire, σ: conductivity [Ω⁻¹m⁻¹] of copper wire, f: frequency [Hz])

In a case of the lower limit frequency, the thickness t of the outer layer (copper) in the two-layer structure conductor was 0.92 times the skin thickness δ of the copper wire. In a case of the upper limit frequency, the thickness t was 0.37 times the skin thickness δ.

For this reason, when the thickness t [m] of the outer layer (copper) is in a range of the following Expression (19), R_s of the two-layer structure conductor is smaller than R_s of the copper wire. Accordingly, it is possible to improve the Q value of a coil.

1.1δ<t<2.7δ  (19)

With the Expression (18), if the conductivity of copper is set to 5.8×10⁷ [Ω⁻¹·m⁻¹], and the magnetic permeability of copper is set to 4π×10⁻⁷ [H/m], which is equal to the magnetic permeability of a vacuum, t [m] given in Expression (19) is represented as in the following Expression (20) as a relational expression depending on a frequency f [Hz].

86×10⁻³×f^−0.5<t<178×10⁻³×f^−0.5  (20)

FIG. 14 illustrates a correlation between a ratio of the skin thickness δ of the copper wire and the radius r₂ of the two-layer structure conductor, and a ratio of the thickness t of the outer layer (copper) in the two-layer structure conductor and the radius r₂ of the two-layer structure conductor, at the lower limit frequency and the upper limit frequency of a frequency region in which R_s of the two-layer structure conductor is smaller than R_s of the copper wire, and D_p of the two-layer structure conductor is smaller than D_p of the copper wire.

Regression analysis was performed on the results by using a linear function, thereby a regression analysis straight line illustrated in FIG. 14 was obtained. The solid line indicates a regression analysis straight line for the lower limit frequency, and the broken line indicates a regression analysis straight line of the upper limit frequency.

In a case of the lower limit frequency, the thickness t of the outer layer (copper) in the two-layer structure conductor was 0.76 times the skin thickness δ of the copper wire. In a case of the upper limit frequency, the thickness t was 0.37 times the skin thickness δ.

For this reason, when the thickness t [m] of the outer layer (copper) is in a range of the following Expression (21), R_s of the two-layer structure conductor is smaller than R_s of the copper wire and D_p is smaller than D_p of the copper wire. Accordingly, it is possible to improve the Q value of a coil.

1.3δ<t<2.7δ  (21)

With the Expression (18), if the conductivity of copper is set to 5.8×10⁷ [Ω⁻¹·m⁻¹], and the magnetic permeability of copper is set to 4π×10⁻⁷ [H/m], which is equal to the magnetic permeability of a vacuum, t [m] given in Expression (21) is represented as in the following Expression (22) as a relational expression depending on a frequency f [Hz].

86×10⁻³×f^−0.5<t<178×10⁻³×f^−0.5  (22)

FIG. 15 illustrates a correlation between a ratio of the skin thickness δ of the copper wire and the radius r₂ of the two-layer structure conductor, and a ratio of the thickness t of the outer layer (copper) in the two-layer structure conductor and the radius r₂ of the two-layer structure conductor, at the lower limit frequency and the upper limit frequency of a frequency region in which R_s of the two-layer structure conductor is smaller than R_s of the copper wire, and D_p of the two-layer structure conductor is smaller than D_p of the copper wire, but L_i is larger than L_i of the copper wire.

Regression analysis was performed on the results by using a linear function, thereby a regression analysis straight line illustrated in FIG. 15 was obtained. The solid line indicates a regression analysis straight line for the lower limit frequency, and the broken line indicates a regression analysis straight line of the upper limit frequency.

In a case of the lower limit frequency, the thickness t of the outer layer (copper) in the two-layer structure conductor was 0.51 times the skin thickness δ of the copper wire. In a case of the upper limit frequency, the thickness t was 0.37 times the skin thickness δ.

For this reason, when the thickness t [m] of the outer layer (copper) is in a range of the following Expression (23), R_s of the two-layer structure conductor is smaller than R_s of the copper wire and D_p is smaller than D_p of the copper wire, but L_i is larger than L_i of the copper wire. Accordingly, it is possible to improve the Q value of a coil.

2.0δ<t<2.7δ  (23)

With the Expression (18), if the conductivity of copper is set to 5.8×10⁷ [Ω⁻¹·m⁻¹], and the magnetic permeability of copper is set to 4π×10⁻⁷ [H/m], which is equal to the magnetic permeability of a vacuum, t [m] given in Expression (23) is represented as in the following Expression (24) as a relational expression depending on a frequency f [Hz].

132×10⁻³×f^−0.5<t<178×10⁻³×f^−0.5  (24)

Generally, the frequency of a current flowing in a cable or a coil is determined by an external factor of equipment using the current, and the like. Examples of equipment to be used include an induction heating device, a non-contact feeding device, a plasma-generating device, a switching power source, a microwave filter, an antenna, and facilities attached to the above-described device.

When the frequency is determined, the thickness of the lead wire is determined by a factor relating to the size, balance between R_s and D_p, or the like. If the frequency and the thickness of the lead wire are determined, the thickness and the cross-sectional area ratio of the outer layer (copper) are selected in accordance with Expression (19), and thus it is possible to reduce resistance in comparison to that of the copper wire.

In a case where ignoring of an influence of the proximity effect is not possible, the thickness and the cross-sectional area ratio of the outer layer (copper) are selected in accordance with Expression (21), and thus it is possible to reduce both of the resistance and the proximity effect in comparison to that of the copper wire.

In a case where the Q value of a coil is increased, the thickness and the cross-sectional area ratio of the outer layer (copper) are selected in accordance with Expression (23), and thus it is possible to increase apparent electric power with respect to the electricity consumption of the coil.

The wire of the present invention may have a structure in which the outer layer is formed from copper, and the inner layer is formed from a material having lower conductivity than that of copper (that is, material having high volume resistivity. For example, metal or an insulating body having lower conductivity than that of copper). The material for forming the inner layer is not limited the exemplified materials.

FIG. 18 illustrates a wire 10A which is a modification example of the wire 10. In the wire 10A, an insulation coating layer 3 is provided on an outer circumferential surface of a conductor portion 11 (on an outer circumferential surface of an outer layer 2). The insulation coating layer 3 coats the outer circumferential surface of the conductor portion 11. The insulation coating layer 3 is the outermost layer of the wire 10A.

The insulation coating layer 3 may be formed by coating with an enamel coating material such as polyester, polyurethane, polyimide, polyester imide, polyamide-imide, and the like. The wire 10A in which the insulation coating layer 3 is formed by using the enamel coating material is an enamel wire.

(Litz Wire)

FIG. 19 illustrates a litz wire 60 which is an example of a litz wire which uses the wire 10A illustrated in FIG. 18. The litz wire 60 is configured to have a plurality of wires 10A which are bundled and twisted.

(Cable)

FIG. 20 illustrates a cable 80 which is an example of a cable in which insulation coating is performed on the litz wire 60. In the cable 80, an insulation coating layer 81 formed of polyethylene and the like is provided on an outer circumferential surface of the litz wire 60.

(High-Frequency Coil)

FIG. 21 illustrates a coil 70 which is an example of a coil (high-frequency coil) which uses the wire 10A illustrated in FIG. 18. The coil 70 includes the wire 10A and a support body 73. The support body 73 includes a body portion 71 and flange portions 72 which are formed at both ends of the body portion 71.

The wire 10A is wound around the body portion 71.

The coil 70 may use the litz wire 60 illustrated in FIG. 19, instead of the wire 10A or the cable 80 may be used as the coil 70.

Example 9

A coil (number of winding of 3) was manufactured by using a copper-coating aluminium wire (cross-sectional area ratio of outer layer: 25%, outer diameter: 1.8 mm), and AC resistance was measured. FIG. 22 illustrates a result.

For comparison, similar calculation was performed on a copper wire having a single-layer structure (Comparative Example 2).

In FIG. 22, the copper-coating aluminium wire was marked as “CA” and the copper wire was marked as “Cu”. The ratio (copper-coating aluminium wire/copper wire) of R_s was set as “CA/Cu”.

As illustrated in FIG. 22, in a frequency region A4, R_s in Example 9 (copper-coating aluminium wire) was less than R_s in Comparative Example 2 (copper wire), and the ratio (copper-coating aluminium wire/copper wire) (CA/Cu) of R_s was smaller than 1.

Example 10

A coil (number of winding of 1) was manufactured by using a copper-coating steel wire (cross-sectional area ratio of outer layer: 25%, outer diameter: 2.0 mm), and AC resistance was measured. FIG. 23 illustrates a result.

In FIG. 23, the copper-coating steel wire was marked as “CS” and the copper wire was marked as “Cu”. The ratio (copper-coating steel wire/copper wire) of R_s was set as “CS/Cu”.

As illustrated in FIG. 23, in a frequency region A5, R_s in Example 10 (copper-coating steel wire) was less than R_s in Comparative Example 2 (copper wire), and the ratio of R_s was smaller than 1.

<Manufacturing Method of High-Frequency Wire>

Subsequently, an example of a method of manufacturing the wire 10 will be described.

A copper tape is vertically attached to a surface of an inner layer body formed from aluminium alloys, steel, nichrome alloys, and the like, for example. A result of attachment is subjected to TIG welding, plasma welding, or the like. Thus, an outer layer formed from copper is formed on an outer circumferential surface of the inner layer body, and a material obtained by the formation is set as a base material. The base material is subjected to wire drawing through a wire drawing die having a plurality of stages, and thus the wire 10 which includes the inner layer 1 and the outer layer 2 may be obtained.

The base material obtained by inserting the inner layer body formed by aluminium alloys and the like into a copper tube is subjected to wire drawing through a wire drawing die having a plurality of stages, and thus the wire 10 which includes the inner layer 1 and the outer layer 2 may be obtained. The copper tube is manufactured by using a general tube manufacturing method.

The outer layer 2 may be formed on an outer circumferential surface of the inner layer 1 by copper plating.

The manufacturing method described herein does not limit the scope of the present invention. The high-frequency wire according to the embodiment of the present invention can also be manufactured by a manufacturing method other than the method exemplified herein.

The above-described embodiments have exemplified a device and a method in order to materialize the technical ideas of the invention. Therefore, in the technical ideas of the invention, the material properties, the shapes, the structures, the arrangements, and the like of the configurational components are not specified. The present invention does not exclude a structure in which a third layer is included in addition to the inner layer and the outer layer. As the regression analysis by using the above-described linear function, a least squares method may be employed.

INDUSTRIAL APPLICABILITY

A high-frequency wire and a high-frequency coil of the present invention can be utilized in the electronic equipment industry including the industry of manufacturing various devices such as a non-contact feeding device, a high-frequency current generation device, and the like including a high-frequency transformer, a motor, a reactor, a choke coil, an induction heating device, a magnetic head, a high-frequency feeding cable, a DC power unit, a switching power source, an AC adapter, eddy current detection-type displacement sensor•flaw sensor, an IH cooking heater, a coil, a feeding cable, and the like.

DESCRIPTION OF THE REFERENCE SYMBOLS

1 INNER LAYER, 2 OUTER LAYER, 10 HIGH-FREQUENCY WIRE (WIRE), 11 CONDUCTOR PORTION, 60 LITZ WIRE, 70 HIGH-FREQUENCY COIL

Claims

1. A high-frequency wire comprising: a conductor portion which comprises an inner layer formed of a material having lower conductivity than copper, and an outer layer which coats the inner layer and is formed of copper, whereinin a frequency range of an AC current for using the high-frequency wire, in a case where a skin thickness δ [m] of a copper wire including a conductor portion formed of pure copper is defined as δ=√(2/ωσμ), a thickness t [m] of the outer layer satisfies 1.1δ<t<2.7δ,here ω indicates an angular frequency of a current, which is represented by 2πf, μ indicates magnetic permeability [H/m] of the copper wire, σ indicates conductivity [Ω−1m−1] of copper, and f indicates a frequency [Hz].

2. The high-frequency wire according to claim 1, wherein the thickness t of the outer layer satisfies 1.3δ<t<2.7δ.

3. The high-frequency wire according to claim 1, wherein the thickness t of the outer layer satisfies 2.0δ<t<2.7δ.

4. The high-frequency wire according to claim 1, wherein an insulation coating layer is provided on an outer circumferential surface of the conductor portion.

5. A high-frequency coil comprising: the high-frequency wire according to claim 4.

6. A litz wire comprising: a plurality of the twisted high-frequency wires according to claim 4.

7. A cable comprising: the litz wire according to claim 6, which is subjected to insulation coating.

8. A coil comprising: the litz wire according to claim 6.