JP2014057429A - Non-contact power transmitter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a non-contact power transmitter capable of reducing in size and weight and capable of preventing reduction of the transmission efficiency.SOLUTION: The non-contact power transmitter includes: a transmission device having a primary coil 20; and a receiver device having a secondary coil 40. The diameter d1 of a space 21 at the primary side of the primary coil 20 is smaller than the diameter d2 of a space 41 at the secondary side of the second coil 40, the ratio of the outer diameter D1 of the primary coil 20 with respect to the outer diameter D2 of the second coil 40 is smaller than 0.7.

Description

  The present invention relates to a contactless power transmission device.

  The non-contact power transmission device includes a power transmission device and a power reception device. The non-contact power transmission device performs non-contact power transmission and electrical signal transmission between the power transmission device and the power reception device. In the non-contact power transmission device, the power transmission efficiency is reduced due to the relative displacement between the primary coil included in the power transmission device and the secondary coil included in the power reception device. For this reason, the conventional non-contact power transmission apparatus sets the ratio of the outer diameter of the primary coil to the outer diameter of the secondary coil to a value within a predetermined range. Note that Patent Document 1 discloses an example of a conventional non-contact power transmission apparatus.

JP 2008-289241 A

  According to the conventional non-contact power transmission apparatus, the primary side space portion located at the center of the primary coil is within the maximum area of the secondary side space portion located at the center of the secondary coil within the standard range of misalignment allowance. Overlapping dimensions are set. In addition, the secondary coil is set to a dimension that completely overlaps the primary coil within the standard range of the allowable positional deviation. For this reason, the outer diameter of the primary coil is larger than the outer diameter of the secondary coil. For this reason, there exists a possibility of increasing the scale of a power transmission apparatus.

  The present invention was created based on the above background, and aims to provide a non-contact power transmission device that can reduce the size of the power transmission device and suppress a decrease in transmission efficiency due to misalignment. To do.

  (1) The first means is a “contactless power transmission device having a power transmission device including a primary coil and a power reception device including a secondary coil, wherein the primary coil is surrounded by a conductive wire. A primary side space portion, and the secondary coil has a secondary side space portion surrounded by a conductive wire, and the diameter of the primary side space portion is smaller than the diameter of the secondary side space portion. And a non-contact power transmission device in which the outer diameter of the primary coil is smaller than the outer diameter of the secondary coil.

(2) The second means includes “a non-contact power transmission device in which the ratio of the outer diameter of the primary coil to the outer diameter of the secondary coil is smaller than 0.7”.
(3) The third means includes “a non-contact power transmission device in which the ratio of the outer diameter of the primary coil to the outer diameter of the secondary coil is greater than 0.42.”

  (4) The second means includes “a non-contact power transmission device in which the primary coil and the secondary coil are planar coils”.

  This non-contact power transmission apparatus contributes to miniaturization of the power transmission apparatus and suppression of a decrease in transmission efficiency due to positional deviation.

The block diagram of the non-contact electric power transmission apparatus in embodiment. It is a figure regarding the charging system in embodiment, (a) And (b) is a block diagram with a different primary coil outer diameter size. It is a figure regarding the primary coil and secondary coil in an embodiment, (a) is a slanting view, (b) is a top view, (c) is a sectional structure figure in a Z3-Z3 line in a top view of (b). It is a figure regarding the primary coil and secondary coil in embodiment, (a)-(c) is a cross-section figure of a prototype. It is a figure regarding the primary coil and secondary coil in embodiment, (a)-(c) is the electric power transmission characteristic figure of a prototype.

(Embodiment)
With reference to FIG. 1, the structure of the non-contact electric power transmission apparatus 1 is demonstrated.
The non-contact power transmission device 1 includes a power transmission device 10 and a power reception device 30. The power transmission device 10 includes a DC voltage source 11, an oscillation unit 12, a drive unit 13, and a primary coil 20.

  The DC voltage source 11 supplies a DC voltage to the drive unit 13. The oscillation unit 12 supplies a clock signal to the drive unit 13. The drive unit 13 switches the direction of the current flowing through the primary coil 20 based on the clock signal output from the oscillation unit 12. The drive unit 13 supplies AC power to the primary coil 20. The primary coil 20 transmits electric power to the secondary coil 40 of the power receiving device 30 using electromagnetic induction.

  The power receiving device 30 includes a secondary coil 40, a rectifier circuit 31, a constant voltage circuit 32, and a load 33. The rectifier circuit 31 rectifies the power received by the secondary coil 40. The constant voltage circuit 32 generates a stabilized voltage from the output of the rectifier circuit 31. The constant voltage circuit 32 supplies the generated voltage to the load 33.

  As shown in FIG. 2, the non-contact power transmission device 1 is applied to a charging system 50 as an electronic device related to non-contact power transmission. The charging system 50 includes a charging stand 60 and a smartphone 70. The charging stand 60 has a primary coil 20 constituted by a planar coil embedded therein. The smart phone 70 has a secondary coil 40 composed of a planar coil embedded therein. The charging stand 60 is supplied with power via a cord 61.

  When charging the battery 71 built in the smartphone 70, the charging stand 60 supplies AC power to the primary coil 20 in the charging stand 60 using the power supplied via the cord 61. The primary coil 20 in the charging stand 60 transmits electric power to the secondary coil 40 in the smartphone 70 disposed on the charging stand 60. The smartphone 70 charges the battery 71 using the power received by the secondary coil 40.

Based on FIG. 3, the shape of the primary coil 20 and the secondary coil 40 is demonstrated.
The primary coil 20 is composed of a circular planar coil having a primary side winding portion 22 on the outer periphery and a primary side space portion 21 formed by being surrounded by the primary side winding portion 22 at the center. The primary winding part 22 is configured by winding a conductive wire around a plane. The secondary coil 40 is composed of a circular planar coil having a secondary winding portion 42 on the outer periphery and a secondary space portion 41 formed at the center portion surrounded by the secondary winding portion 42. Is done. The secondary winding part 42 is configured by winding a conductive wire around a plane. In the primary coil 20, the size of the primary space 21 is a diameter d1, and the size of the coil is an outer diameter D1. In the secondary coil 40, the size of the secondary space 41 is a diameter d2, and the size of the coil is an outer diameter D2.

  The secondary coil 40 in the smartphone 70 is arranged at a position facing the primary coil 20 in the charging stand 60 when charging the battery 71. Secondary coil 40 differs in relative position with primary coil 20 according to the position on charging stand 60 where smart phone 70 is arranged.

  It is desirable that the charging system 50 has a large allowable value for positional deviation between the charging stand 60 and the smartphone 70. The positional shift is defined as the distance between the center of the primary coil 20 and the center of the secondary coil 40 when either the center of the primary coil 20 or the center of the secondary coil 40 is shifted from the center line 80. It is desirable that the primary coil 20 and the secondary coil 40 can suppress a reduction in power transmission efficiency when a positional shift occurs. The power transmission efficiency is defined as the ratio of the power received by the secondary coil 40 to the power consumed by the primary coil 20 to transmit power when the battery 71 is charged. Moreover, as for the primary coil 20 and the secondary coil 40, it is desirable that the fall of the electric power which the smart phone 70 can consume in the case where position shift arises can be suppressed.

  When the outer diameter D1 of the primary coil 20 larger than the outer diameter D2 of the secondary coil 40 is required, the charging stand 60 has a larger size than the smartphone 70 as shown in FIG. When the outer diameter D1 of the primary coil 20 can be made smaller than the outer diameter D2 of the secondary coil 40, the charging stand 60 has a smaller size than the smartphone 70 as shown in FIG. be able to.

  Here, this inventor confirmed the position shift characteristic of electric power transmission efficiency about the case where the outer diameter D1 of the primary coil 20 is made smaller than the secondary coil 40 diameter D2. The misregistration characteristics of the power transmission efficiency were confirmed using a plurality of types of prototypes having different outer diameters D1 and secondary coils 40 of the primary coil 20 and a diameter D2.

FIG. 4 shows the dimensions of the primary coil 20 and the secondary coil 40 in the prototype.
In the reference coil shown in FIG. 4A, the outer diameter D1 of the primary coil 20 is set to a value larger than the outer diameter D2 of the secondary coil 40. In the comparative 1 coil shown in FIG. 4B and the comparative 2 coil shown in FIG. 4C, the outer diameter D <b> 1 of the primary coil 20 is smaller than the outer diameter D <b> 2 of the secondary coil 40. In the reference coil, the comparison 1 coil, and the comparison 2 coil, the diameter d1 of the primary space 21 of the primary coil 20 and the diameter d2 of the secondary space 41 of the secondary coil 40 have the same value. Each coil dimension is described as a standardized dimension in which the diameter d1 of the primary side space 21 of the primary coil 20 is 1. In the reference coil, the comparison 1 coil, and the comparison 2 coil, the ratio of the outer diameter D1 of the primary coil 20 to the outer diameter D2 of the secondary coil 40 is set to 1.33, 0.7, and 0.42, respectively. . The reference coil, the comparison 1 coil, and the comparison 2 coil are set to have the same self-inductance value.

The confirmation results of the power transmission characteristics of the reference coil, the comparison 1 coil, and the comparison 2 coil are shown in FIGS. 5 (a), 5 (b), and 5 (c).
The positional shift used for the X axis indicates the distance that one of the center of the primary coil 20 and the center of the secondary coil 40 is shifted from the center line 80.

  The power transmission characteristic is measured as the positional deviation dependency of the output voltage and efficiency. The measurement was performed under the conditions described below. The power transmission side switches the current supplied to the primary coil 20 using a 12-v DC voltage with a clock signal having a period of 8.3 μs. The power receiving side rectifies the power received by the secondary coil 40 and supplies a current of 2 A to the load. The output voltage is a measured value of the voltage applied to the load. The efficiency is a value obtained by measuring a ratio between the power consumed by the load and the power supplied from the 12-v DC voltage source on the transmission side.

As shown in FIG. 5, it can be seen that the comparative 1 coil and the comparative 2 coil have the same power transmission characteristics as the reference coil.
The inventor of the present application infers the reason why the comparative 1 coil and the comparative 2 coil exhibit the same power transmission characteristics as the reference coil as follows.

  The electric power generated by the secondary coil 40 depends on the number of conductive wires of the secondary side winding portion 42 where the magnetic flux is linked and the number of magnetic flux lines linked with the secondary side winding portion 42. When there is no decrease in the number of conductive wires of the secondary side winding portion 42 where the magnetic flux due to the positional deviation is linked and the number of magnetic flux lines linked with the secondary side winding portion 42, the power transmission characteristics are deteriorated due to the positional deviation. Can be suppressed.

The primary coil 20 and the secondary coil 40 suppress the decrease in the number of conductive wires of the secondary side winding portion 42 where the magnetic flux due to the positional deviation is linked as follows.
The power transmission device 10 generates a magnetic flux by supplying a pulse current to the conductive wire of the primary coil 20. At this time, the magnetic flux is generated along a path that passes through the primary space 21. The secondary coil 40 generates an induced electromotive force by linking the magnetic flux generated in the primary coil 20 with the conductive wire of the secondary winding portion 42. At this time, when the magnetic flux is in a path passing through the secondary side space portion 41 of the secondary coil 40, the number of conductive wires of the secondary side winding portion 42 interlinked with the magnetic flux becomes the largest. When the diameter of the primary space portion 21 of the primary coil 20 is smaller than the diameter of the secondary space portion 41 of the secondary coil 40, the primary space portion 21 of the primary coil 20 is not affected even when misalignment occurs. It is located in the 40 secondary side space part 41. For this reason, a decrease in the number of magnetic fluxes passing through the secondary side space 41 of the secondary coil 40 at the time of occurrence of misalignment is suppressed. For this reason, when the diameter of the primary side space part 21 of the primary coil 20 is smaller than the diameter of the secondary side space part 41 of the secondary coil 40, the fall by position shift of electric power transmission efficiency is suppressed.

The primary coil 20 and the secondary coil 40 suppress the decrease in the number of magnetic flux lines interlinking with the secondary winding part 42 due to the positional deviation as follows.
The number of magnetic fluxes generated by the primary coil 20 is affected by the area of the portion where the primary side winding portion 22 of the primary coil 20 and the secondary side winding portion 42 of the secondary coil 40 face each other. When the primary coil 20 and the secondary coil 40 have a small variation in the facing area between the primary side winding portion 22 and the secondary side winding portion 42 due to misalignment, a decrease in transmission efficiency due to misalignment is suppressed.

  Based on the above idea, the power transmission characteristics are such that even if the ratio of the outer diameter D1 of the primary coil 20 to the outer diameter D2 of the secondary coil 40 is smaller than 0.42, fluctuations in the power transmission characteristics due to misalignment are suppressed. Can be guessed.

  In the non-contact power transmission device 1 of the embodiment, the diameter d1 of the primary space 21 of the primary coil 20 is smaller than the diameter d2 of the secondary space of the secondary coil 40, and the outside of the secondary coil 40 The ratio of the outer diameter D1 of the primary coil 20 to the diameter D2 is set to a value smaller than 0.7.

The non-contact power transmission device 1 has the following effects.
(1) The non-contact power transmission device 1 includes the power transmission device 10 and the power reception device 30. The power transmission device 10 includes a primary coil 20 having a primary space 21. The power receiving device 30 includes a secondary coil 40 having a secondary space portion 41. The diameter d1 of the primary space 21 of the primary coil is smaller than the diameter d2 of the secondary space of the secondary coil, and the outer diameter D1 of the primary coil is smaller than the outer diameter D2 of the secondary coil. According to this configuration, in the non-contact power transmission device 1 that can suppress a decrease in transmission efficiency due to misalignment, the power transmission device 10 can be reduced in size and weight.

(2) In the charging system 50 to which the non-contact power transmission device 1 is applied, the charging stand 60 can be downsized. For this reason, user convenience is improved.
(Other embodiments)
This non-contact power transmission device includes other embodiments. Hereinafter, the modification of embodiment as other embodiment of this non-contact electric power transmission apparatus is shown. The following modifications can be combined with each other.

  -The primary coil 20 and the secondary coil 40 of embodiment have the primary side space part 21 and the secondary side space part 41. FIG. However, the structure of the primary coil 20 and the secondary coil 40 is not restricted to the content illustrated by embodiment. For example, when the primary coil 20 and the secondary coil 40 are arranged at positions where the primary coil 20 and the secondary coil 40 face each other, the magnetic core is arranged at the center.

  -The non-contact electric power transmission apparatus 1 of embodiment is applied to the charging system 50 which has the charging stand 60 and the smart phone 70. FIG. However, application examples are not limited to the contents exemplified in the embodiment. For example, the non-contact power transmission device 1 of the modification is applied to a charging system having a charging stand and an electric toothbrush. Or it applies to other charging systems.

  -The non-contact electric power transmission apparatus 1 of embodiment is applied to the charging system 50 which has the charging stand 60 and the smart phone 70. FIG. However, application examples are not limited to the contents exemplified in the embodiment. For example, the non-contact power transmission device 1 of the modification is applied to a non-contact information reading system having a non-contact card reader and an IC card.

(Additional note regarding means for solving the problem)
Means for solving the problem can be described as the following additional means.
(1) Note 1 means that "the primary coil has a primary winding portion formed by winding a conductive wire on a plane, and the secondary coil is formed by winding a conductive wire on a plane. A non-contact power transmission device having a secondary winding portion ”.

  DESCRIPTION OF SYMBOLS 1 ... Non-contact electric power transmission apparatus 1, 10 ... Power transmission apparatus, 20 ... Primary coil, 21 ... Primary side space part, 30 ... Power receiving apparatus, 40 ... Secondary coil, 41 ... Secondary side space part, d1 ... Primary side space Part diameter, d2 ... secondary space part diameter, D1 ... primary coil outer diameter, D2 ... secondary coil outer diameter.

Claims (4)

A non-contact power transmission device having a power transmission device including a primary coil and a power reception device including a secondary coil,
The primary coil has a primary space formed by being surrounded by a conductive wire,
The secondary coil has a secondary space portion formed by being surrounded by a conductive wire,
The non-contact power transmission device, wherein a diameter of the primary space portion is smaller than a diameter of the secondary space portion, and an outer diameter of the primary coil is smaller than an outer diameter of the secondary coil. The non-contact power transmission device according to claim 1, wherein a ratio of an outer diameter of the primary coil to an outer diameter of the secondary coil is smaller than 0.7. The non-contact power transmission device according to claim 1 or 2, wherein a ratio of an outer diameter of the primary coil to an outer diameter of the secondary coil is larger than 0.42. The non-contact power transmission device according to claim 1, wherein the primary coil and the secondary coil are configured by planar coils.