JP2013247822A - Wireless power feeding device, wireless power receiving device, wireless power feeding system, and electrical instrument - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wireless power feeding device capable of suppressing unnecessary electromagnetic field radiation.SOLUTION: A wireless power feeding device, which has a power feeding coil and feeds power to a wireless power receiving device provided with a power receiving coil by power transmission of an electromagnetic induction type utilizing the power feeding coil and the power receiving coil, has a configuration in which: the power feeding coil forms a linear signal path; the linear signal path is configured by forming a plurality of coil portions on the substantially same plane with a single wire of a conductive material; and when current flows through one end point of the single wire to the other end point, the current flows in opposite directions to each other in each of the neighboring coil portions.

Description

  The present invention relates to a wireless power feeding device, a wireless power receiving device, a wireless power feeding system including these, and an electrical apparatus including the wireless power receiving device.

  2. Description of the Related Art In recent years, so-called wireless power feeding technology that transmits electric power in a non-contact manner by electromagnetic field coupling between coiled radiators is becoming widespread. The technology related to “Okudashi Charging (registered trademark)” adopted in the smartphone “AQUOS PHONE (registered trademark) SH-13C” released in August 2011 is representative.

  FIG. 8 is an example of a schematic block diagram of a conventional wireless power supply system, which is an example of a configuration according to a standard document (Non-patent Document 1) issued by WPC (Wireless Power Consortium). In this figure, in the power supply apparatus 911, the internal inverter circuit 914 converts the DC power supplied from the external power source 910 such as an AC adapter into 110 kHz to 205 kHz AC power, and radiates it as an AC magnetic field through the power supply coil 912. .

  In the power receiving device 921, the power receiving coil 922 picks up an AC magnetic field, and the rectifier circuit 924 converts it into DC power, and supplies power to the battery 926 and the like via the voltage stabilization circuit 925. The final output to the battery 926 or the like is 5 W at the maximum in the case of WPC ver. Magnetic plates (913, 923) are usually attached to the back surfaces of the feeding coil 912 and the receiving coil 922 for the purpose of electromagnetic shielding.

  FIG. 9 is a schematic diagram of the structure of the coils (912, 922) serving as radiators of electromagnetic fields. For example, the WPC standard A1 coil, which is considered to be the most standard coil at present, is defined as a circular coil having an outer shape of 43 mm as disclosed in Non-Patent Document 1. In this figure, the circular coil 511 is formed by winding a linear signal path, and is attached to the surface of the magnetic plate 504 as described above. The electrical connection between the electronic circuit and the coil 511 is generally realized by soldering two end points of the linear signal path forming the coil 511 to the circuit board 503.

JP 2010-187495 A

System Description Wireless Power Transfer Volume I: Low Power Part 1: Interface Definition Version 1.0.2 April 2011

  However, in the wireless power feeder of the prior art, there is a problem that the AC magnetic field of W class power radiated from the power feeding coil not only travels to the power receiving coil but unnecessarily spreads to the surroundings. FIG. 10 is a schematic diagram showing the state of the magnetic field around the coil shown in FIG. In this figure, the power feeding coil 912 and the power receiving coil 922 are close to each other and face each other. The magnetic field lines of the alternating magnetic field have a loop shape that wraps the two coils (912, 922), but the loop diameter extends over a wide range because there is no restriction.

  When a high-power AC magnetic field is received, there is a risk of causing malfunctions in the case of surrounding electronic devices and sensitivity deterioration in the case of wireless devices such as radios. In the case of the human body, it is known that a strong magnetic field causes a stimulating action and the like, and there is a concern about adverse health effects. Therefore, the International Commission on Non-Ionizing Radiation Protection (ICNIRP) has established guidelines for magnetic field strengths that do not adversely affect health, and it is essential to comply with them.

  Of course, the problem of unnecessary electromagnetic field radiation becomes more serious as the output power of the wireless power feeder is increased. The charging base for mobile phones already on the market is a low-power device of about 5W, but if power supply technology starts to be adopted in general household appliances such as PCs, TVs, refrigerators, vacuum cleaners, washing machines, etc., 10W High output to ˜100 W is inevitable, and accordingly, suppression technology of unnecessary electromagnetic field radiation becomes an important issue.

  In view of the above-described problems, an object of the present invention is to provide a wireless power feeding apparatus that can suppress unnecessary electromagnetic field radiation. It is another object of the present invention to provide a wireless power receiving device, a wireless power feeding system, and an electric device that can use the wireless power feeding device.

  A wireless power feeding apparatus according to the present invention includes a power feeding coil, and wirelessly feeds power to the wireless power receiving apparatus having a power receiving coil by electromagnetic induction power transmission using the power feeding coil and the power receiving coil. In the power supply device, the form of the power supply coil is a linear signal path, and the linear signal path has a plurality of coil portions formed on a substantially same plane by a single wire made of a conductive material. In this embodiment, when a current flows from one end point of the single wire to the other end point, a current flows in a direction opposite to each other in each of the adjacent coil portions. According to this configuration, unnecessary electromagnetic field radiation can be suppressed.

  More specifically, the linear signal path may be formed by connecting partial single wires constituting each of the plurality of coil portions in series. More specifically, the partial single wires may be soldered to a predetermined circuit board and connected in series via a wiring pattern of the circuit board.

  More specifically, in the linear signal path, each of the plurality of coil portions may be wound in a substantially rectangular shape. More specifically, in the above-described configuration, in the linear signal path, each of the adjacent coil portions is arranged such that one side of the outer periphery of one of the coil portions is along one side of the outer periphery of the other coil portion. It is good also as a structure arranged.

  More specifically, in the linear signal path, each of the plurality of coil portions may be wound in a substantially circular shape.

  Moreover, the wireless power receiving apparatus according to the present invention has a power receiving coil used for the power transmission, and is configured to receive the power supply from the wireless power feeding apparatus having the above configuration. More specifically, the configuration of the power receiving coil may be the configuration of the linear signal path.

  A wireless power feeding system according to the present invention includes the wireless power feeding device having the above-described configuration, and a wireless power receiving device formed to receive the power feeding from the wireless power feeding device, including a power receiving coil used for the power transmission. It is set as the structure which has these. More specifically, the configuration of the power receiving coil may be the configuration of the linear signal path.

  According to another aspect of the present invention, there is provided an electrical apparatus including the wireless power receiving apparatus having the above-described configuration and a battery charged with electric power obtained by the wireless power receiving apparatus, and driven using the electric power charged in the battery. To do.

  According to the wireless power feeder according to the present invention, it is possible to suppress unnecessary electromagnetic field radiation. Moreover, according to the wireless power receiving apparatus, the wireless power feeding system, and the electric device according to the present invention, the wireless power feeding apparatus according to the present invention can be used.

It is a block diagram regarding the wireless electric power feeding system which concerns on this embodiment. It is explanatory drawing regarding the structure of the electric power feeding part and power receiving part which concern on 1st Embodiment. It is explanatory drawing regarding the magnetic field in the circumference | surroundings of a feeding coil and a receiving coil. It is explanatory drawing regarding the magnetic field in the circumference | surroundings of a feeding coil and a receiving coil. It is explanatory drawing regarding the structure of the electric power feeding part and power receiving part which concern on 2nd Embodiment. It is explanatory drawing regarding the structure of the electric power feeding part and power receiving part which concern on 3rd Embodiment. It is explanatory drawing regarding the structure of the electric power feeding part and power receiving part which concern on 4th Embodiment. It is a block diagram regarding the wireless power feeding system of a prior art example. It is explanatory drawing regarding the structure of the coil of a prior art example. It is explanatory drawing regarding the magnetic field around the coil of a prior art example.

  Embodiments of the present invention will be described below by taking each of the first to fourth embodiments as an example.

1. First Embodiment [Overall Configuration of Wireless Power Supply System]
First, the first embodiment will be described. FIG. 1 is a block diagram relating to the wireless power feeding system 9 according to the present embodiment.

  As shown in FIG. 1, the wireless power feeding system 9 includes a power feeding device 1 (wireless power feeding device) and a power receiving device 2 (wireless power receiving device). The power feeding device 1 is connected to an external power source PW (for example, an AC adapter connected to a commercial power source), and the power receiving device 2 is connected to a battery BAT (storage battery). The wireless power feeding system 9 is configured to feed power from the power feeding device 1 to the power receiving device 2 by electromagnetic induction power transmission.

  The power feeding device 1 includes a power feeding unit 11 and an inverter circuit 12. The inverter circuit 12 converts DC power supplied from the external power supply PW into AC power of 110 kHz to 205 kHz, for example, and supplies the AC power to the power supply unit 11.

  The power supply unit 11 includes a power supply coil 11a, a magnetic plate 11b, and a circuit board 11c. The feeding coil 11a generates an alternating magnetic field when a current flows by the power supplied from the inverter circuit 12. The magnetic body plate 11b serves as an electromagnetic shield in the power feeding device 1. The circuit board 11 c plays a role of connecting the feeding coil 11 a to the output side of the inverter circuit 12. A more detailed structure of the power supply unit 11 will be described again.

  The power receiving device 2 includes a power receiving unit 21, a rectifier circuit 22, and a voltage stabilization circuit 23. The power receiving unit 21 includes a power receiving coil 21a, a magnetic plate 21b, and a circuit board 21c.

  The power receiving coil 21a generates an electromotive force by an alternating magnetic field generated by the power feeding coil 11a (that is, by electromagnetic induction), and outputs alternating current power. The magnetic body plate 21 b serves as an electromagnetic shield in the power receiving device 2. The circuit board 21 c plays a role of connecting the power receiving coil 21 a to the input side of the rectifier circuit 22. A more detailed structure of the power reception unit 21 will be described again.

  The rectifier circuit 22 converts AC power output from the power receiving coil 21a into DC power and outputs the DC power. The DC power output from the rectifier circuit 22 is supplied to the battery BAT via the voltage stabilization circuit 23 for stabilizing the voltage. As a result, the battery BAT is charged with the electric power obtained by the power receiving device 2. In the present embodiment, the output power of the power receiving device 2 is supplied to the battery, but the supply destination of the output power is not limited to such a form.

  The wireless power feeding system 9 is suitable for portable electric devices, for example. In this case, the electric device includes the power receiving device 2 and the battery BAT, and is configured to be driven using electric power charged in the battery BAT. The external power supply PW and the power feeding device 1 are provided in a charger corresponding to the electric device. According to this aspect, it is possible to charge the battery BAT by bringing the electric device close to the charger. However, the application target of the wireless power feeding system 9 is not limited to such a form.

[Detailed configuration of power feeding unit and power receiving unit]
Next, more detailed configurations of the power feeding unit 11 and the power receiving unit 21 will be described. The power feeding unit 11 and the power receiving unit 21 basically have a common structure. FIG. 2 schematically shows this common structure (referred to as “common structure 30” for convenience).

  As shown in FIG. 2, the common structure 30 includes a single long copper wire 31, a magnetic plate 32, and a circuit board 33. The circuit board 33 is provided with a first terminal 33-1 and a second terminal 33-2.

  The copper wire 31 is a single wire made of a conductive material, and the first coil portion C1 and the second coil portion C2 are formed adjacent to each other on the same plane. Each coil part (C1, C2) is a part which forms the coil by having a form in which a part of the copper wire 31 is wound in the same direction on the same plane.

  The copper wire 31 starts from one end point and winds in a “8” shape while going back and forth between the place where the first coil part C1 is formed and the place where the second coil part C2 is formed. After that, the other end point is reached. Thus, both the 1st coil part C1 and the 2nd coil part C2 which were each wound circularly by the copper wire 31 are formed so that it may mutually adjoin on the same plane.

  The copper wire 31 is placed on the magnetic plate 32. One end point of the copper wire 31 is electrically connected to the first terminal 33-1 by soldering, and the other end point of the copper wire 31 is electrically connected to the second terminal 33-2 by soldering. Has been.

  The copper wire 31 is wound counterclockwise in the first coil portion C1 and clockwise in the second coil portion C2 when viewed from the first terminal 33-1 side. That is, the first coil portion C1 and the second coil portion C2 are wound in directions that are opposite to each other.

  Therefore, when a current flows from one end point of the copper wire 31 to the other end point, the current flows through the first coil portion C1 and the second coil portion C2 in directions opposite to each other. In other words, in the portion where the first coil portion C1 and the second coil portion C2 are close to each other (proximity portion P1 shown in FIG. 2), the current direction of the copper wire 31 is not the reverse direction but is substantially the same direction. The 1st coil part C1 and the 2nd coil part C2 are arranged.

  In the power feeding section 11, the copper wire 31 corresponds to the power feeding coil 11a, the magnetic plate 32 corresponds to the magnetic plate 11b, and the circuit board 33 corresponds to the circuit board 11c. On the other hand, in the power receiving unit 21, the copper wire 31 corresponds to the power receiving coil 21a, the magnetic plate 32 corresponds to the magnetic plate 21b, and the circuit board 33 corresponds to the circuit board 21c.

  In the power feeding unit 11, the first terminal 33-1 and the second terminal 33-2 are connected to the output side of the inverter circuit 12, and the copper wire 31 (feeding coil 11a) is connected to the power supplied from the inverter circuit 12. A current flows. On the other hand, in the power receiving unit 11, the first terminal 33-1 and the second terminal 33-2 are connected to the input side of the rectifier circuit 22, and the AC power output from the copper wire 31 (the power receiving coil 21a) is the rectifier circuit. 22 is input.

  When feeding power from the power feeding device 1 to the power receiving device 2, the first coil portions C1 of the power feeding coil 11a and the power receiving coil 21a face each other, and the second coil portions C2 of the power feeding coil 11a and the power receiving coil 21a are opposed to each other. The power feeding device 1 and the power receiving device 2 are positioned so that the coil axes of the first coil portions C1 coincide with each other and the coil axes of the second coil portions C2 coincide with each other. The Then, in such a positioned state, a current is passed through the feeding coil 11a.

  Thereby, electromagnetic induction by the first coil portions C1 of the power feeding coil 11a and the power receiving coil 21a and electromagnetic induction by the second coil portions C2 of the power feeding coil 11a and the power receiving coil 21a are efficiently performed, and good power feeding efficiency is achieved. It is possible to obtain

[About suppression of unnecessary electromagnetic field radiation]
When power feeding from the power feeding device 1 to the power receiving device 2 is performed, from a portion (referred to as “first coil coupling portion CC1” for convenience) composed of the first coil portion C1 of the power feeding coil 11a and the power receiving coil 21a. As the magnetic field lines appear, the magnetic field lines emerge from a portion (referred to as “second coil coupling portion CC2” for convenience) formed by the second coil portion C2 of the power feeding coil 11a and the power receiving coil 21a.

  However, in the present embodiment, when a current is passed through the feeding coil 11a, the currents flow in directions opposite to each other between adjacent coil parts (the first coil part C1 and the second coil part C2 in the feeding coil 11a).

  For this reason, when power is supplied from the power supply device 1 to the power receiving device 2, a part of the magnetic field lines (for example, about a fraction) from the first coil coupling portion CC1 is bent in the course of the second coil. Part of the lines of magnetic force (for example, about a fraction of a portion) sucked into the coupling part CC2 and emitted from the second coil coupling part CC2 is bent into the course and sucked into the first coil coupling part CC1. As a result, the first coil coupling part CC1 and the second coil coupling part CC2 absorb each other's magnetic field lines, so that the magnetic field lines are compactly folded and are prevented from spreading far.

  3 and 4 are diagrams schematically showing the state of the magnetic field around the power feeding coil 11a and the power receiving coil 21a. FIG. 3 shows a diagram in the case of the present embodiment (when currents flow in directions opposite to each other in the first coil portion and the second coil portion of the feeding coil), and FIG. 4 shows the feeding coil. For reference, a diagram of a case where it is assumed that a current flows through the first coil portion and the second coil portion in the same direction (other conditions are the same as in the present embodiment) is shown for reference.

  As shown in FIG. 4, when a current flows in the same direction in the first coil portion C1 and the second coil portion C2 of the feeding coil 11a, it is unnecessary as in the conventional case (see FIG. 10). Magnetic field lines spread far away. On the other hand, as shown in FIG. 3, in the case of the present embodiment, the spread of unnecessary lines of magnetic force is suppressed as compared with the case shown in FIG.

  As described above, according to the wireless power feeding system 9 (particularly, the power feeding device 1) of the present embodiment, the directions of currents flowing through the first coil portion C1 and the second coil portion C2 of the power feeding coil 11a are opposite to each other. Unnecessary electromagnetic field radiation leaking out from the feeding coil 11a and the receiving coil 21a is suppressed. Therefore, it is possible to reduce electromagnetic interference to surrounding electronic devices and magnetic field exposure to surrounding human bodies. Such an effect is particularly remarkable when the wireless power feeding system 9 is for high power.

2. Second Embodiment Next, a second embodiment will be described. In addition, 2nd Embodiment is the same as that of 1st Embodiment fundamentally except the part regarding the structure of the electric power feeding part 11 and the power receiving part 21. FIG. In the following description, emphasis is placed on the description of parts different from the first embodiment, and description of common parts may be omitted.

  The power feeding unit 11 and the power receiving unit 21 basically have a common structure. FIG. 5 schematically shows this common structure (referred to as “common structure 40” for convenience). As shown in FIG. 5, the common structure 40 includes a single long copper wire 41, a magnetic plate 42, and a circuit board 43. The circuit board 43 is provided with a first terminal 43-1 and a second terminal 43-2.

  The copper wire 41 is a single wire made of a conductive material, and the first coil portion C1a and the second coil portion C2a are formed adjacent to each other on the same plane. In addition, each coil part (C1a, C2a) is a part which forms the coil by being the form by which a part of copper wire 41 was wound in the same direction on the same plane.

  The copper wire 41 starts from one end point, is wound a plurality of times in a circular and counterclockwise direction at the location where the first coil portion C1a is formed, and then moves to the location where the second coil portion C2a is formed. It is circular and wound clockwise several times, and then reaches the other end point. Thus, both the 1st coil part C1a and the 2nd coil part C2a which were each wound by circular shape with the copper wire 41 are formed so that it may mutually adjoin on the same plane.

  The copper wire 41 is placed on the magnetic plate 42. One end point of the copper wire 41 is electrically connected to the first terminal 43-1 by soldering, and the other end point of the copper wire 41 is electrically connected to the second terminal 43-2 by soldering. Has been.

  The copper wire 41 is wound counterclockwise in the first coil portion C1a and clockwise in the second coil portion C2a when viewed from the first terminal 43-1 side. That is, the first coil portion C1a and the second coil portion C2a are wound in directions that are opposite to each other.

  Therefore, when a current flows from one end point of the copper wire 41 to the other end point, the current flows through the first coil portion C1a and the second coil portion C2a in directions opposite to each other. In other words, in the portion where the first coil portion C1a and the second coil portion C2a are close to each other (proximity portion P1a shown in FIG. 5), the current direction of the copper wire 41 is not the reverse direction but is substantially the same direction. The 1st coil part C1a and the 2nd coil part C2a are arranged.

  In the power feeding unit 11, the copper wire 41 corresponds to the power feeding coil 11a, the magnetic plate 42 corresponds to the magnetic plate 11b, and the circuit board 43 corresponds to the circuit board 11c. On the other hand, in the power receiving unit 21, the copper wire 41 corresponds to the power receiving coil 21a, the magnetic plate 42 corresponds to the magnetic plate 21b, and the circuit board 43 corresponds to the circuit board 21c.

  Further, in the power feeding unit 11, the first terminal 43-1 and the second terminal 43-2 are connected to the output side of the inverter circuit 12, and the copper wire 41 (feeding coil 11a) is connected to the power supplied from the inverter circuit 12. A current flows. On the other hand, in the power receiving unit 11, the first terminal 43-1 and the second terminal 43-2 are connected to the input side of the rectifier circuit 22, and the AC power output from the copper wire 41 (power receiving coil 21a) is the rectifier circuit. 22 is input.

  When power is supplied from the power feeding device 1 to the power receiving device 2, the first coil portions C1a of the power feeding coil 11a and the power receiving coil 21a face each other, and the second coil portions C2a of the power feeding coil 11a and the power receiving coil 21a are facing each other. The power feeding device 1 and the power receiving device 2 are positioned so that the coil axes of the first coil portions C1a coincide with each other and the coil axes of the second coil portions C2a coincide with each other. The Then, in such a positioned state, a current is passed through the feeding coil 11a.

  Thereby, electromagnetic induction by the first coil portions C1a of the power feeding coil 11a and the power receiving coil 21a and electromagnetic induction by the second coil portions C2a of the power feeding coil 11a and the power receiving coil 21a are efficiently performed, and good power feeding efficiency is achieved. It is possible to obtain

  As described above, in the second embodiment, the geometric winding method of the copper wire is different from that in the first embodiment. However, from the viewpoint of current distribution in the copper wire, the first embodiment and the second embodiment are almost the same, and can be regarded as almost the same as the magnetic field circuit. That is, when a current is passed through the power feeding coil 11a, currents flow in directions opposite to each other between adjacent coil parts (the first coil part C1a and the second coil part C2a in the power feeding coil 11a).

  Therefore, also in the wireless power feeding system 9 (particularly the power feeding device 1) of the second embodiment, unnecessary electromagnetic field radiation leaking to the surroundings from the power feeding coil 11a and the power receiving coil 21a is suppressed by the same principle as in the first embodiment. Therefore, it is possible to reduce electromagnetic interference to surrounding electronic devices and magnetic field exposure to surrounding human bodies.

  In addition, it can select arbitrarily about which of the winding method of 1st Embodiment and the winding method of 2nd Embodiment is adopted as a winding method of a copper wire. For example, a more preferable method of winding the copper wire may be employed depending on the manufacturing equipment of the power feeding coil 11a and the power receiving coil 21a.

3. Third Embodiment Next, a third embodiment will be described. In addition, 3rd Embodiment is the same as that of 1st Embodiment fundamentally except the part regarding the structure of the electric power feeding part 11 and the power receiving part 21. FIG. In the following description, emphasis is placed on the description of parts different from the first embodiment, and description of common parts may be omitted.

  The power feeding unit 11 and the power receiving unit 21 basically have a common structure. FIG. 6 schematically shows this common structure (referred to as “common structure 50” for convenience). As shown in FIG. 6, the common structure 50 includes a first partial single line 51-1, a second partial single line 51-2, a magnetic plate 52, and a circuit board 53.

  The circuit board 53 is provided with a first terminal 53-1, a second terminal 53-2, a first intermediate terminal 53-m1, and a second intermediate terminal 53-m2. The first intermediate terminal 53-m1 and the second intermediate terminal 53-m2 are electrically connected by a wiring pattern 53-p on the circuit board 53.

  The first partial single wire 51-1 is a single wire formed of a conductive material such as copper, and forms a first coil portion C1b wound in a substantially rectangular shape. One end point of the first partial single wire 51-1 is electrically connected to the first terminal 53-1 by soldering, and the other end point is electrically connected to the first intermediate terminal 53-m1 by soldering. Has been.

  The second partial single wire 51-2 is a single wire formed of a conductive material such as copper, and forms a second coil portion C2b wound in a substantially rectangular shape. One end point of the second partial single wire 51-2 is electrically connected to the second intermediate terminal 53-m2 by soldering, and the other end point is electrically connected to the second terminal 53-2 by soldering. Has been.

  Each partial single wire (51-1, 51-2) is placed on the magnetic plate 52. Each coil part (C1b, C2b) is the part which forms the coil by the form where the partial single wire was wound in the same direction on the same plane. The coil portions (C1b, C2b) are adjacent to each other on the same plane and are arranged close to each other.

  As described above, the first partial single wire 51-1 and the second partial single wire 51-2 are separate components (separately manufactured), but are soldered to the circuit board 53, so that the wiring pattern 53- They are electrically connected in series with p interposed.

  That is, the first partial single line 51-1, the wiring pattern 53-p, and the second partial single line 51-2 are connected in series in this order, so that one single line (for convenience, referred to as “coupled single line S1”). ) Is formed. It can be seen that the coupled single wire S1 is formed so that both the first coil portion C1b and the second coil portion C2b are close to each other on the same plane.

  As viewed from the first terminal 53-1, the first coil portion C1b is wound counterclockwise, and the second coil portion C2b is wound clockwise. That is, the first coil part C1b and the second coil part C2b are wound in directions opposite to each other.

  Therefore, when a current flows from one end point of the coupled single line S1 to the other end point, the current flows through the first coil portion C1b and the second coil portion C2b in directions opposite to each other. In other words, in the portion where the first coil portion C1b and the second coil portion C2b are close to each other (proximity portion P1b shown in FIG. 6), the current direction of the coupled single wire S1 is not the reverse direction but is substantially the same direction. The 1st coil part C1b and the 2nd coil part C2b are arranged.

  In the power supply unit 11, the coupled single line S1 corresponds to the power supply coil 11a, the magnetic plate 52 corresponds to the magnetic plate 11b, and the circuit board 53 corresponds to the circuit board 11c. On the other hand, in the power receiving unit 21, the coupled single wire S1 corresponds to the power receiving coil 21a, the magnetic plate 52 corresponds to the magnetic plate 21b, and the circuit board 53 corresponds to the circuit board 21c.

  Further, in the power feeding unit 11, the first terminal 53-1 and the second terminal 53-2 are connected to the output side of the inverter circuit 12, and are connected to the coupled single line S1 (power feeding coil 11a) by the power supplied from the inverter circuit 12. A current flows. On the other hand, in the power receiving unit 11, the first terminal 53-1 and the second terminal 53-2 are connected to the input side of the rectifier circuit 22, and the AC power output from the coupled single line S1 (power receiving coil 21a) is the rectifier circuit. 22 is input.

  When feeding power from the power feeding device 1 to the power receiving device 2, the first coil portions C1b of the power feeding coil 11a and the power receiving coil 21a face each other, and the second coil portions C2b of the power feeding coil 11a and the power receiving coil 21a are facing each other. The power feeding device 1 and the power receiving device 2 are positioned so that the coil axes of the first coil portions C1b coincide with each other and the coil axes of the second coil portions C2b coincide with each other. The Then, in such a positioned state, a current is passed through the feeding coil 11a.

  Thereby, electromagnetic induction by the first coil portions C1b of the power feeding coil 11a and the power receiving coil 21a and electromagnetic induction by the second coil portions C2b of the power feeding coil 11a and the power receiving coil 21a are efficiently performed, and good power feeding efficiency is achieved. It is possible to obtain

  As described above, also in the wireless power feeding system 9 of the third embodiment, when a current is passed through the power feeding coil 11a, adjacent coil parts (the first coil part C1b and the second coil part C2b in the power feeding coil 11a) are connected. Current flows in directions opposite to each other. Therefore, the wireless power feeding system 9 (particularly the power feeding device 1) of the third embodiment also suppresses unnecessary electromagnetic field radiation that leaks from the power feeding coil 11a and the power receiving coil 21a to the surroundings based on the same principle as in the first embodiment.

  In the third embodiment, when forming each coil part (C1b, C2b), a process of winding a copper wire into a complicated shape is not required. Since each coil part (C1b, C2b) is merely a rectangular coil when viewed individually, each partial single wire (51-1, 51-2) is easy to manufacture. Furthermore, the power feeding coil 11a or the power receiving coil 21a can be formed by soldering each partial single wire (51-1, 51-2) to the circuit board 53. Easy.

  Furthermore, in each coil part (C1b, C2b) in the third embodiment, one side of the outer periphery (one side of the proximity part P1b) of the first coil part C1b is one side of the outer periphery of the second coil part C2b (one side of the proximity part P1b). ). For this reason, a sufficiently close region between the coil portions (C1b, C2b) is secured (specifically, a length corresponding to the length of these one sides facing each other). Thus, the magnetic field coupling between each coil part is reinforce | strengthened very much by maximizing the degree of proximity | contact of each coil part in the proximity part P1b.

4). Fourth Embodiment Next, a fourth embodiment will be described. In addition, 4th Embodiment is the same as that of 1st Embodiment fundamentally except the part regarding the structure of the electric power feeding part 11 and the power receiving part 21. FIG. In the following description, emphasis is placed on the description of parts different from the first embodiment, and description of common parts may be omitted.

  The power feeding unit 11 and the power receiving unit 21 basically have a common structure. FIG. 7 schematically shows this common structure (referred to as “common structure 60” for convenience). As shown in FIG. 7, the common structure 60 includes a first partial single line 61-1, a second partial single line 61-2, a third partial single line 61-3, a magnetic plate 62, and a circuit board 63. .

  The circuit board 63 includes a first terminal 63-1, a second terminal 63-2, a first intermediate terminal 63-m1, a second intermediate terminal 63-m2, a third intermediate terminal 63-m3, and a fourth intermediate terminal. 63-m4 is provided. The first intermediate terminal 63-m1 and the second intermediate terminal 63-m2 are electrically connected by a first wiring pattern 63-p1 on the circuit board 63. The third intermediate terminal 63-m3 and the fourth intermediate terminal 63-m4 are electrically connected by a second wiring pattern 63-p2 on the circuit board 63. The first wiring pattern 63-p1 is provided on the front surface of the circuit board 63, and the second wiring pattern 63-p2 is provided on the back surface of the circuit board 63.

  The first partial single wire 61-1 is a single wire formed of a conductive material such as copper, and forms a first coil portion C1c wound in a substantially rectangular shape. The first partial single wire 61-1 has one end point electrically connected to the first terminal 63-1 by soldering, and the other end point electrically connected to the first intermediate terminal 63-m1. Has been.

  The second partial single wire 61-2 is a single wire formed of a conductive material such as copper, and forms a second coil portion C2c wound in a substantially rectangular shape. One end point of the second partial single wire 61-2 is electrically connected to the second intermediate terminal 63-m2 by soldering, and the other end point is electrically connected to the third intermediate terminal 63-m3 by soldering. It is connected.

  The third partial single wire 61-3 is a single wire formed of a conductive material such as copper, and forms a third coil portion C3c wound in a substantially rectangular shape. One end point of the third partial single wire 61-3 is electrically connected to the fourth intermediate terminal 63-m4 by soldering, and the other end point is electrically connected to the second terminal 63-2 by soldering. Has been.

  The partial single wires (61-1, 61-2, 61-3) are placed on the magnetic plate 62. Each coil part (C1c, C2c, C3c) is the part which forms the coil by the form by which the partial single wire was wound in the same direction on the same plane. The first coil part C1c and the second coil part C2c are adjacent to each other on the same plane and are arranged close to each other. The second coil portion C2c and the third coil portion C3c are adjacent to each other on the same plane and are disposed so as to be close to each other.

  As described above, each partial single wire (61-1, 61-2, 61-3) is a separate component (manufactured separately), but each wiring pattern is soldered to the circuit board 63. (63-p1, 63-p2) are electrically connected in series.

  That is, the first partial single line 61-1, the first wiring pattern 63-p1, the second partial single line 61-2, the second wiring pattern 63-p2, and the third partial single line 61-3 are connected in series in this order. Thus, one single line (referred to as “coupled single line S2” for convenience) is formed. The coupled single wire S2 is formed so that both the first coil portion C1c and the second coil portion C2c are close to each other on the same plane, and both the second coil portion C2c and the third coil portion C3c are the same. It can be seen that they are formed so as to be close to each other on a plane.

  As viewed from the first terminal 63-1, the first coil portion C1c is wound counterclockwise, the second coil portion C2c is wound clockwise, and the third coil portion C3c is wound counterclockwise. Yes. That is, the first coil portion C1c and the second coil portion C2c are wound in the directions opposite to each other, and the second coil portion C2c and the third coil portion C3c are wound in the directions opposite to each other. Yes.

  Therefore, when a current flows from one end point of the coupled single wire S2 to the other end point, a current flows in the first coil portion C1c and the second coil portion C2c in directions opposite to each other, and the second coil portion C2c As a result, current flows through the third coil portion C3c in directions opposite to each other.

  In other words, in the portion where the first coil portion C1c and the second coil portion C2c are close to each other (proximity portion P1c shown in FIG. 7), the current direction of the coupled single wire S2 is not the reverse direction but is substantially the same direction. The 1st coil part C1c and the 2nd coil part C2c are arranged. Furthermore, in the portion where the second coil portion C2c and the third coil portion C3c are close to each other (proximity portion P2c shown in FIG. 7), the current direction of the coupled single line S2 is not the reverse direction but is substantially the same direction. A second coil part C2c and a third coil part C3c are arranged.

  In the power feeding unit 11, the coupled single line S2 corresponds to the power feeding coil 11a, the magnetic plate 62 corresponds to the magnetic plate 11b, and the circuit board 63 corresponds to the circuit board 11c. On the other hand, in the power receiving unit 21, the coupled single wire S2 corresponds to the power receiving coil 21a, the magnetic plate 62 corresponds to the magnetic plate 21b, and the circuit board 63 corresponds to the circuit board 21c.

  In the power feeding section 11, the first terminal 63-1 and the second terminal 63-2 are connected to the output side of the inverter circuit 12, and are connected to the coupled single line S2 (power feeding coil 11a) by the power supplied from the inverter circuit 12. A current flows. On the other hand, in the power receiving unit 11, the first terminal 63-1 and the second terminal 63-2 are connected to the input side of the rectifier circuit 22, and the AC power output from the coupled single line S2 (power receiving coil 21a) is the rectifier circuit. 22 is input.

  When feeding power from the power feeding device 1 to the power receiving device 2, the first coil portions C1c of the power feeding coil 11a and the power receiving coil 21a face each other and the second coil portions C2c of the power feeding coil 11a and the power receiving coil 21a are opposed to each other. So that the third coil portion C3c of the power feeding coil 11a and the power receiving coil 21a face each other (in other words, the coil axes of the first coil portions C1c coincide with each other and the second coil portions C2c The power feeding device 1 and the power receiving device 2 are positioned so that the coil axes coincide with each other and the coil axes of the third coil portions C3c coincide with each other. Then, in such a positioned state, a current is passed through the feeding coil 11a.

  Thereby, the electromagnetic induction by the 1st coil part C1c of the feeding coil 11a and the receiving coil 21a, the electromagnetic induction by the 2nd coil part C2c of the feeding coil 11a and the receiving coil 21a, and the 1st of the feeding coil 11a and the receiving coil 21a Electromagnetic induction by the three coil portions C3c is efficiently performed, and it is possible to obtain good power supply efficiency.

  As described above, also in the wireless power feeding system 9 of the fourth embodiment, when a current is passed through the power feeding coil 11a, adjacent coil parts (the first coil part C1c and the second coil part C2c in the power feeding coil 11a, and The current flows through the second coil portion C2c and the third coil portion C3c) in directions opposite to each other. For this reason, the wireless power feeding system 9 (particularly the power feeding device 1) of the fourth embodiment also suppresses unnecessary electromagnetic field radiation leaking to the surroundings from the power feeding coil 11a and the power receiving coil 21a by the same principle as in the first embodiment.

  In the fourth embodiment, the number of coil portions is three, but may be four or more. Even in this case, the configuration according to the fourth embodiment is adopted, and when a current is passed through the feeding coil 11a, the current flows in a direction opposite to each other between adjacent coil portions. Thus, the effect of suppressing unnecessary electromagnetic field radiation can be obtained. The number of coil portions can be arbitrarily set to two or more according to the product specifications provided with the wireless power feeding system 9.

  In addition, in 4th Embodiment, in forming each coil part (C1c, C2c, C3c), the process of winding a copper wire in a complicated shape is not required. Since each coil part (C1c, C2c, C3c) is a simple rectangular coil when viewed as a single unit, each partial single wire (61-1, 61-2, 61-3) is easy to manufacture. Further, since each of the partial single wires (61-1, 61-2, 61-3) is soldered to the circuit board 63, the power feeding coil 11a or the power receiving coil 21a can be formed. 9 is easy to manufacture.

  Further, in the first coil portion C1c and the second coil portion C2c in the fourth embodiment, one side of the outer periphery (one side of the proximity portion P1c) of the first coil portion C1c is one side of the outer periphery of the second coil portion C2c (proximity portion). It is arranged along one side of P1c. Therefore, a region in which the coil portions (C1c, C2c) are very close to each other is sufficiently secured (specifically, a length corresponding to the length of these one sides facing each other). Thus, the magnetic field coupling between each coil part is reinforce | strengthened very much by maximizing the degree of proximity | contact of each coil part in the proximity part P1c.

  Still further, in the second coil portion C2c and the third coil portion C3c in the fourth embodiment, one side of the outer periphery of the second coil portion C2c (one side of the proximity portion P2c) is one side of the outer periphery of the third coil portion C3c (proximity portion). It is arranged along one side of P2c. Therefore, a sufficiently close region between the coil portions (C2c, C3c) is ensured (specifically, a length corresponding to the length of one side of the coils). Thus, the magnetic field coupling between each coil part is reinforce | strengthened very much by maximizing the degree of proximity | contact of each coil part in the proximity part P2c.

5. Others As described above, the power feeding device 1 of each embodiment has the power feeding coil 11a, and the electromagnetic induction method using the power feeding coil 11a and the power receiving coil 21a with respect to the power receiving device 2 having the power receiving coil 21a. Power is supplied by power transmission.

  The form of the feeding coil 11a is a linear signal path. The linear signal path corresponds to the copper wire 31 in the case of the first embodiment, the copper wire 41 in the case of the second embodiment, and the combined single line S1 in the case of the third embodiment. In the case of the fourth embodiment, the coupled single line S2 is applicable.

  The linear signal path is a form in which a plurality of coil portions are formed on the same plane by a single wire made of a conductive material, and when a current flows from one end point of this single wire to the other end point, adjacent coils In each part, current flows in directions opposite to each other. Therefore, according to the power supply device 1 of each embodiment, it is possible to suppress unnecessary electromagnetic field radiation as already described.

  Note that the coil portions are not necessarily formed on the same plane, and may be misaligned within a range that does not hinder normal wireless power feeding. The form (particularly the shape and position) of the coil part on the power feeding coil side and the coil part on the power receiving coil side do not necessarily have to be completely the same, and may differ within a range that does not hinder normal wireless power feeding. Absent. However, if the forms are greatly different, the magnetic fields of the coil portions may interfere with each other, leading to a reduction in power supply efficiency. Therefore, it is preferable that the difference in the form is as small as possible. The power receiving device 2 of each embodiment includes a power receiving coil 21 a and is configured to receive power from the power feeding device 1. In addition, the form of the receiving coil 21a is also the above-described linear signal path, similarly to the form of the feeding coil 11a.

  The power feeding unit 11 and the power receiving unit 21 may be formed of parts having the same specifications. If this is the case, it is not necessary to separately prepare components for the power feeding unit 11 and components for the power receiving unit 21, and it becomes easy to reduce the manufacturing cost of the wireless power feeding system 9.

  The configuration of the present invention can be variously modified in addition to the above embodiment without departing from the spirit of the invention. That is, the above-described embodiment is an example in all respects, and should be considered not restrictive. The technical scope of the present invention is shown not by the above description of the embodiment but by the scope of the claims, and is understood to include all modifications within the meaning and scope equivalent to the scope of the claims. Should.

  The present invention is applicable to an electromagnetic induction type wireless power feeding system and the like.

DESCRIPTION OF SYMBOLS 1 Feeding device 11 Feeding part 11a Feeding coil 11b Magnetic board 11c Circuit board 12 Inverter circuit 2 Power receiving apparatus 21 Power receiving part 21a Power receiving coil 21b Magnetic board 21c Circuit board 22 Rectifier circuit 23 Voltage stabilization circuit 30, 40, 50, 60 Common structure 31, 32 Copper wire 32, 42, 52, 62 Magnetic plate 33, 43, 53, 63 Circuit board 51-1, 61-1 First partial single wire 51-2, 61-2 Second partial single wire 9 Wireless Power supply system BAT Battery PW External power source S1, S2 Coupling single line CC1 First coil coupling section CC2 Second coil coupling section C1, C1a, C1b, C1c First coil section C2, C2a, C2b, C2c Second coil section C3c Third coil Part P1, P1a, P1b, P1c, P2c Proximity part

Claims (11)

Has a feeding coil,
A wireless power feeder having a power receiving coil, which is powered by electromagnetic induction power transmission using the power feeding coil and the power receiving coil.
The form of the feeding coil is a linear signal path,
The linear signal path is:
A plurality of coil portions are formed on substantially the same plane by a single wire made of a conductive material,
The wireless power feeding apparatus according to claim 1, wherein when a current flows from one end point of the single wire to the other end point, a current flows in a direction opposite to each other in each of the adjacent coil portions. The linear signal path is:
The wireless power feeding apparatus according to claim 1, wherein the partial single wires constituting each of the plurality of coil portions are formed by being connected in series. Each of the partial single wires is
The wireless power feeder according to claim 2, wherein the wireless power feeder is soldered to a predetermined circuit board and connected in series via a wiring pattern of the circuit board. In the linear signal path,
4. The wireless power feeding apparatus according to claim 1, wherein each of the plurality of coil portions is wound in a substantially rectangular shape. 5. In the linear signal path,
Each of the adjacent coil portions is
The wireless power feeding apparatus according to claim 4, wherein one side of the outer periphery of the one coil portion is disposed along one side of the outer periphery of the other coil portion. In the linear signal path,
The wireless power feeding apparatus according to claim 1, wherein each of the plurality of coil portions is wound in a substantially circular shape. Having a power receiving coil used for the power transmission;
A wireless power receiving apparatus, wherein the wireless power receiving apparatus is configured to receive the power supply from the wireless power supply apparatus according to any one of claims 1 to 6. The form of the receiving coil is:
The wireless power receiving apparatus according to claim 7, wherein the wireless power receiving apparatus is the linear signal path. The wireless power supply apparatus according to any one of claims 1 to 6,
A power receiving coil used for the power transmission, and a wireless power receiving device formed to receive the power feeding from the wireless power feeding device;
A wireless power feeding system comprising: The form of the receiving coil is:
The wireless power feeding system according to claim 9, wherein the wireless signal feeding path is the linear signal path. A wireless power receiving device according to claim 7 or claim 8,
A battery charged with the electric power obtained by the wireless power receiving device,
An electric device that is driven using electric power charged in the battery.

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