Patent Publication Number: US-2022230803-A1

Title: Coil component and wireless power transmitting device having the same

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application claims the benefit of Japanese Patent Application No. 2021-007760, filed on Jan. 21, 2021, the entire disclosure of which is incorporated by reference herein. 
     BACKGROUND 
     Field 
     The present disclosure relates to a coil component and a wireless power transmitting device having the same. 
     Description of Related Art 
     International Publication WO 2013/073314 describes a method of adjusting an NFC (Near-Field Communication) communication coverage area. In this method, in addition to a main coil antenna, a sub-coil antenna connected to the main coil antenna is provided. 
     However, the method described in International Publication WO 2013/073314 cannot extend the communication coverage area efficiently. 
     SUMMARY 
     It is therefore an object of the present disclosure to provide a coil component capable of efficiently extending the communication coverage area and a wireless power transmitting device having such a coil component. 
     A coil component according to one embodiment of the present disclosure includes a first coil pattern, a second coil pattern connected to the first coil pattern, and a magnetic member covering the first and second coil patterns in the axial direction thereof. The first and second coil patterns are arranged side by side in a first direction perpendicular to the axial direction. The first coil pattern has a first protrusion protruding in a second direction perpendicular to the axial direction and the first direction from a first outer peripheral end of the magnetic member in the second direction. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The above features and advantages of the present disclosure will be more apparent from the following description of certain preferred embodiments taken in conjunction with the accompanying drawings, in which: 
         FIG. 1  is a schematic plan view of a terminal holder incorporating a coil component according to one embodiment; 
         FIGS. 2A and 2B  are schematic plan views of the terminal holder  1  in a case where the smartphone  3  is placed offset; 
         FIG. 3  is a schematic plan view for explaining the structure of a coil component  100  according to one embodiment; 
         FIG. 4  is a schematic cross-sectional view taken along the line A-A in  FIG. 3 ; 
         FIG. 5  is a schematic cross-sectional view taken along the line B-B in  FIG. 3 ; 
         FIG. 6  is a schematic cross-sectional view taken along the line C-C in  FIG. 3 ; 
         FIG. 7  is a schematic cross-sectional view taken along the line D-D in  FIG. 3 ; 
         FIG. 8  is a schematic view for explaining in more detail the positional relation between the first to third coil patterns CP 1  to CP 3  and the magnetic member  7 ; 
         FIGS. 9A to 9C  are schematic views for explaining a change in the magnetic flux depending on the position of the outer peripheral end  52  of the magnetic member  7 ; 
         FIG. 10  is a schematic plan view for explaining the structure of a coil component  100   a  according to a modification; and 
         FIG. 11  is a block diagram of a wireless power transmitting device  60  including the coil component  100 . 
     
    
    
     DETAILED DESCRIPTION OF THE EMBODIMENTS 
     Preferred embodiments of the present disclosure will be explained below in detail with reference to the accompanying drawings. 
       FIG. 1  is a schematic plan view of a terminal holder  1  incorporating a coil component according to one embodiment. 
     The terminal holder  1  illustrated in  FIG. 1  has a placing surface  2  on which a mobile terminal such as a smartphone  3  is placed. The placing surface  2  has an xy plane. A coil pattern for NFC (Near-Field Communication) and a coil pattern for wireless power transmission, which are to be described later, are disposed below (in the z-direction) the placing surface  2 . Thus, placing the smartphone  3  on the terminal holder  1  allows near-field communication between the terminal holder  1  and the smartphone  3  and allows the smartphone  3  to be charged through wireless power transmission. The device incorporating the coil component according to the present disclosure is not limited to the terminal holder  1  illustrated in  FIG. 1  but may be any device capable of placing thereon the smartphone  3 , such as a center console provided the interior of a vehicle. 
     In  FIG. 1 , the smartphone  3  is placed at substantially the center of the placing surface  2  in the x-direction. However, the width of the placing surface  2  in the x-direction is larger than the length of the smartphone  3  in the x-direction, so that the smartphone  3  may be placed offset in the positive x-direction (three o&#39;clock direction in the drawing) as illustrated in  FIG. 2A  or may be placed offset in the negative x-direction (nine o&#39;clock direction in the drawing) as illustrated in  FIG. 2B . Thus, the terminal holder  1  needs to be designed such that it can perform near-field communication with the smartphone  3  even when the smartphone  3  is placed offset from the center. 
       FIG. 3  is a schematic plan view for explaining the structure of a coil component  100  according to one embodiment.  FIG. 4  is a schematic cross-sectional view taken along the line A-A in  FIG. 3 ,  FIG. 5  is a schematic cross-sectional view taken along the line B-B in  FIG. 3 ,  FIG. 6  is a schematic cross-sectional view taken along the line C-C in  FIG. 3 , and  FIG. 7  is a schematic cross-sectional view taken along the line D-D in  FIG. 3 . 
     As illustrated in  FIGS. 3 to 7 , the coil component  100  according to the present embodiment includes a substrate  4  which is, e.g., a PET film, first to fourth coil patterns CP 1  to CP 4  provided on surfaces  4   a  and  4   b  of the substrate  4 , and a magnetic member  7 . On the back surface of the magnetic member  7 , the casing of the terminal holder  1  and a metal member  8  including a circuit board are provided. That is, the magnetic member  7  is arranged between the first to fourth coil patterns CP 1  to CP 4  and the metal member  8 . Typically, the existence of the metal member  8  near the coil pattern deteriorates antenna efficiency; however, in the present embodiment, the magnetic member  7  is arranged between the coil pattern and the metal member, so that the magnetic member  7  functions as a magnetic path to suppress deterioration of antenna efficiency. The upper surfaces of the first to fourth coil patterns CP 1  to CP 4  are covered with the casing of the terminal holder  1  and an insulating member  6  which is, e.g., a protective film. 
     The first to third coil patterns CP 1  to CP 3  are each an antenna coil for NFC, and the fourth coil pattern CP 4  is a power transmitting coil for wireless power transmission. The first to third coil patterns CP 1  to CP 3  are arranged side by side such that the first coil pattern CP 1  is interposed between the second and third coil patterns CP 2  and CP 3 . The first coil pattern CP 1  located at the center serves as a main antenna for performing communication around substantially the center portion in the x-direction, and the second and third coil patterns CP 2  and CP 3  located on both sides of the first coil pattern CP 1  in the x-direction each serve as a sub antenna for extending the communication coverage area in the x-direction. The axial directions of the first to third coil patterns CP 1  to CP 3  are each the z-direction. Such an arrangement in which the second and third coil patterns CP 2  and CP 3  (sub antennas) are arranged on both sides of the first coil pattern CP 1  (main antenna) allows the communication coverage area to extend in the x-direction. Thus, in whichever position on the placing surface  2  the smartphone  3  is placed, near-field communication can be performed properly. The x-direction is an example of a first direction, and the y-direction is an example of a second direction. 
     The first to third coil patterns CP 1  to CP 3  each have an opening. In the example illustrated in  FIGS. 3 to 7 , the opening width of the first coil pattern CP 1  in the x-direction is larger than those of the second and third coil patterns CP 2  and CP 3  in the x-direction. The opening width in the y-direction is the same for all the first to third coil patterns CP 1  to CP 3 . The fourth coil pattern CP 4  is arranged inside the opening area of the first coil pattern CP 1 . The axial direction of the coil pattern CP 4  is also the x-direction. The coil axes of the first and fourth coil patterns CP 1  and CP 4  may coincide with each other or may differ from each other in position in the x- or y-direction. Such an arrangement in which the fourth coil pattern CP 4  is arranged inside the opening area of the coil pattern CP 1  allows all the first to fourth coil patterns CP 1  to CP 4  to be formed on surfaces of the substrate  4 , thus reducing the number of components. Further, the first to fourth coil patterns CP 1  to CP 4  can be formed at a time, thus simplifying the production process. 
     The first coil pattern CP 1  includes a conductor pattern  11  formed on the surface  4   a  of the substrate  4  and a conductor pattern  12  formed on the surface  4   b  of the substrate  4 . The second coil pattern CP 2  includes a conductor pattern  21  formed on the surface  4   a  of the substrate  4 , a conductor pattern  22  formed on the surface  4   b  of the substrate  4 , and a via conductor  23  penetrating the substrate  4  so as to connect the conductor patters  21  and  22 . The third coil pattern CP 3  includes a conductor pattern  31  formed on the surface  4   a  of the substrate  4 , a conductor pattern  32  formed on the surface  4   b  of the substrate  4 , and a via conductor  33  penetrating the substrate  4  so as to connect the conductor patterns  31  and  32 . The fourth coil pattern CP 4  includes a conductor pattern  41  formed on the surface  4   a  of the substrate  4 , a conductor pattern  42  formed on the surface  4   b  of the substrate  4 , and a via conductor  43  penetrating the substrate  4  so as to connect the conductor patterns  41  and  42 . The first to third coil patterns CP 1  to CP 3  are connected in series to constitute one antenna coil. 
     The first coil pattern CP 1  has about one turn, and the second and third coil patterns CP 2  and CP 3  each have about two turns in the example illustrated in  FIGS. 3 to 7 , while the number of turns of each of the first to third coil patterns CP 1  to CP 3  is not limited to a particular value. When the numbers of turns of the second and third coil patterns CP 2  and CP 3  (sub antennas) are each made larger than the number of turns of the first coil pattern CP 1  (main antenna) as in the example illustrated in  FIGS. 3 to 7 , antenna characteristics on both sides in the x-direction can be enhanced. On the other hand, when the number of turns of the first coil pattern CP 1  (main antenna) is made larger than the numbers of turns of the second and third coil patterns CP 2  and CP 3  (sub antennas), antenna characteristics at substantially the center portion in the x-direction can be enhanced. The fourth coil pattern CP 4 , which is a power transmitting coil for wireless power transmission, requires a large inductance and is thus made larger in the number of turns than the first to third coil patterns. 
     The fourth coil pattern CP 4  for wireless power transmission is entirely covered with the magnetic member  7  in the z-direction. On the other hand, for the first to third coil patterns CP 1  to CP 3  for NFC, although most part of the opening area overlaps the magnetic member  7  in the z-direction, a part thereof does not overlap the magnetic member  7 . That is, the first to third coil patterns CP 1  to CP 3  each have a protrusion protruding in the x- or y-direction from the outer peripheral end of the magnetic member  7 . 
       FIG. 8  is a schematic view for explaining in more detail the positional relation between the first to third coil patterns CP 1  to CP 3  and the magnetic member  7 . 
     As illustrated in  FIG. 8 , the magnetic member  7  has outer peripheral ends  51  to  54 . The outer peripheral end is the end portion of the magnetic member  7  in the positive y-direction (twelve o&#39;clock direction in the drawing) and extends in the x-direction. The outer peripheral end  52  is the end portion of the magnetic member  7  in the positive x-direction (three o&#39;clock direction in the drawing) and extends in the y-direction. The outer peripheral end  53  is the end portion of the magnetic member  7  in the negative x-direction (nine o&#39;clock direction in the drawing) and extends in the y-direction. The outer peripheral end  54  is the end portion of the magnetic member  7  in the negative y-direction (six o&#39;clock direction in the drawing) and extends in the x-direction. The width Wy of the magnetic member  7  in the y-direction, i.e., the distance between the outer peripheral ends  51  and  54  is smaller than the opening width Dy of each of the first to third coil patterns CP 1  to CP 3  in the y-direction. On the other hand, the width Wx of the magnetic member  7  in the x-direction, i.e., the distance between the outer peripheral ends  52  and  53  is larger than the opening width Dx of the first coil pattern CP 1  in the x-direction. The outer peripheral end  51  is an example of a first outer peripheral end, the outer peripheral end  52  is an example of a second outer peripheral end, and the outer peripheral end  53  is an example of a third outer peripheral end. 
     The first coil pattern CP 1  has sections S 11  to S 14 . The section S 11  is positioned in the positive y-direction (twelve o&#39;clock direction in the drawing) and extends in the x-direction. The section S 12  is positioned in the positive x-direction (three o&#39;clock direction in the drawing) and extends in the y-direction. The section S 13  is positioned in the negative x-direction (nine o&#39;clock direction in the drawing) and extends in the y-direction. The section S 14  is positioned in the negative y-direction (six o&#39;clock direction in the drawing) and extends in the x-direction. The sections S 12  and  13  overlap in most parts thereof the magnetic member  7 , while the sections S 11  and 
     S 14  do not overlap the magnetic member  7 . That is, the section S 11  constitutes a protrusion (first protrusion) protruding in the positive y-direction from the outer peripheral end  51  of the magnetic member  7 , and the section S 14  constitutes a protrusion protruding in the negative y-direction from the outer peripheral end  54  of the magnetic member  7 . The sections S 11  and S 14  of the first coil pattern CP 1  thus each constitute the protrusion that does not overlap the magnetic member  7  in the z-direction, so that magnetic flux is suppressed from extending in the positive and negative y-directions but correspondingly extends in the positive and negative x-directions. 
     The section S 11  is constituted by the conductor pattern  12 , and the section S 14  is constituted by the conductor pattern  11 . A part of the section S 12  that is constituted by the conductor pattern  12  is connected to one end of the conductor pattern  21  constituting the second coil pattern CP 2  through the conductor pattern  22  and via conductor  23 . The other end of the conductor pattern  21  is connected to a part of the section S 12  that is constituted by the conductor pattern  11 . Similarly, a part of the section S 13  that is constituted by the conductor pattern  12  is connected to one end of the conductor pattern  31  constituting the third coil pattern CP 3  through the conductor pattern  32  and via conductor  33 . The other end of the conductor pattern  31  is connected to a part of the section S 13  that is constituted by the conductor pattern  11 . The section S 14  is terminated at a pair of terminals E 1  and E 2 . In the example illustrated in  FIG. 8 , the first coil pattern CP 1  has a connecting pattern extending in the x-direction so as to connect the conductor patterns  12  and  22  and a connecting pattern extending in the x-direction so as to connect the conductor patterns  11  and  21 . The widths of these connection patterns in the x-direction are smaller than the opening width of the second coil pattern CP 2  in the x-direction. Similarly, the first coil pattern CP 1  has a connecting pattern extending in the x-direction so as to connect the conductor patterns  12  and  32  and a connecting pattern extending in the x-direction so as to connect the conductor patterns  11  and  31 . The widths of these connection patterns in the x-direction are smaller than the opening width of the third coil pattern CP 3  in the x-direction. 
     The winding direction of the first coil pattern CP 1  and the winding directions of the second and third coil patterns CP 2  and CP 3  are opposite. Thus, for example, when a current is made to flow from the terminal E 1  to the terminal E 2 , the current flows in the first coil pattern CP 1  in the left-hand direction (counterclockwise direction), and the current flows in the second and third coil patterns CP 2  and CP 3  in the right-handed direction (clockwise direction). The first to third coil patterns CP 1  to C 3  are thus connected such that the magnetic flux generated from the first coil pattern CP 1  and the magnetic fluxes generated from the second and third coil patterns CP 2  and CP 3  have mutually opposite phases, with the result that the magnetic flux generated from the first coil pattern CP 1  and the magnetic fluxes generated from the second and third coil patterns CP 2  and CP 3  mainly strengthen each other. 
     The second coil pattern CP 2  has sections S 21  to S 24 . The section S 21  is positioned in the positive y-direction (twelve o&#39;clock direction in the drawing) and extends in the x-direction. The section S 22  is positioned in the positive x-direction (three o&#39;clock direction in the drawing) and extends in the y-direction. The section S 23  is positioned in the negative x-direction (nine o&#39;clock direction in the drawing) and extends in the y-direction. The section S 24  is positioned in the negative y-direction (six o&#39;clock direction in the drawing) and extends in the x-direction. The section S 23  overlaps in most part thereof the magnetic member  7 , while the sections S 21 , S 22 , and 
     S 24  do not overlap the magnetic member  7 . That is, the section S 21  constitutes a protrusion (third protrusion) protruding in the positive y-direction from the outer peripheral end  51  of the magnetic member  7 , the section S 22  constitutes a protrusion (second protrusion) protruding in the positive x-direction from the outer peripheral end  52  of the magnetic member  7 , and the section S 24  constitutes a protrusion protruding in the negative y-direction from the outer peripheral end  54  of the magnetic member  7 . The sections S 21  and S 24  of the second coil pattern CP 2  thus each constitute the protrusion that does not overlap the magnetic member  7  in the z-direction, so that the magnetic flux is suppressed from extending in the positive and negative y-directions but correspondingly extends in the positive x-direction. 
     The third coil pattern CP 3  has sections S 31  to S 34 . The section S 31  is positioned in the positive y-direction (twelve o&#39;clock direction in the drawing) and extends in the x-direction. The section S 32  is positioned in the positive x-direction (three o&#39;clock direction in the drawing) and extends in the y-direction. The section S 33  is positioned in the negative x-direction (nine o&#39;clock direction in the drawing) and extends in the y-direction. The section S 34  is positioned in the negative y-direction (six o&#39;clock direction in the drawing) and extends in the x-direction. The section S 32  overlaps in most part thereof the magnetic member  7 , while the sections S 31 , S 33 , and S 34  do not overlap the magnetic member  7 . That is, the section S 31  constitutes a protrusion (fifth protrusion) protruding in the positive y-direction from the outer peripheral end  51  of the magnetic member  7 , the section S 33  constitutes a protrusion (fourth protrusion) protruding in the negative x-direction from the outer peripheral end  53  of the magnetic member  7 , and the section S 34  constitutes a protrusion protruding in the negative y-direction from the outer peripheral end  54  of the magnetic member  7 . The sections S 31  and S 34  of the third coil pattern CP 3  thus each constitute the protrusion that does not overlap the magnetic member  7  in the z-direction, so that the magnetic flux is suppressed from extending in the positive and negative y-directions but correspondingly extends in the negative x-direction. 
       FIGS. 9A to 9C  are schematic views for explaining a change in the magnetic flux depending on the position of the outer peripheral end  52  of the magnetic member  7 . 
       FIG. 9A  illustrates a case where the position X 1  of the outer peripheral end  52  of the magnetic member  7  in the x-direction overlaps the opening area of the second coil pattern CP 2 . In this case, a magnetic flux ϕ 1   a  generated from the first coil pattern CP 1  and a magnetic flux ϕ 2  generated from the second coil pattern CP 2  strengthen each other, whereby the communication coverage area extends in the positive x-direction. In particular, when the position X 1  of the outer peripheral end  52  of the magnetic member  7  in the x-direction is located in the positive x-direction relative to the center position X 2  of the second coil pattern CP 2  in the x-direction, that is, when the distance between the position X 1  and the section S 22  of the second coil pattern CP 2  is less than ½ of the opening width of the second coil pattern CP 2  in the x-direction, the communication coverage area extends largely in the positive x-direction. The magnetic flux generated from the first coil pattern CP 1  includes components ϕ 1   b  and ϕ 1   c  which act so as to cancel the magnetic flux ϕ 2 ; however, in the example illustrated in  FIG. 9A , the components ϕ 1   b  and ϕ 1   c  are included in comparatively small amounts. 
     On the other hand, as illustrated in  FIG. 9B , when the section S 22  of the second coil pattern CP 2  does not protrude in the positive x-direction from the magnetic member  7 , the magnetic flux component ϕ 1   b  increases, so that the extension of the communication coverage area in the positive x-direction is suppressed as compared with the case of  FIG. 9A . Further, as illustrated in  FIG. 9C , when the position X 1  of the outer peripheral end  52  of the magnetic member  7  in the x-direction is located in the negative x-direction relative to the center position X 2  of the second coil pattern CP 2  in the x-direction, that is, when the distance between the position X 1  and the section S 22  of the second coil pattern CP 2  is equal to or more than ½ of the opening width of the second coil pattern CP 2  in the x-direction, the magnetic flux component ϕ 1   c  increases, so that the extension of the communication coverage area in the positive x-direction is suppressed as compared with the case of  FIG. 9A . Considering the above, the position X 1  of the outer peripheral end  52  of the magnetic member  7  in the x-direction and the second coil pattern CP 2  preferably have the positional relation illustrated in  FIG. 9A . The same applies for the positional relation between the position of the outer peripheral end  53  of the magnetic member  7  in the x-direction and the third coil pattern CP 3 , although not illustrated. 
     As described above, in the present embodiment, the first to third coil patterns CP 1  to CP 3  and the magnetic member  7  have the positional relation described above, so that the magnetic fluxes interlinking with the first to third coil patterns CP 1  to CP 3  extend in the positive and negative directions. As a result, in whichever position on the placing surface  2  of the terminal holder  1  the smartphone  3  is placed, communication between the terminal holder  1  and the smartphone  3  can be performed properly. 
       FIG. 10  is a schematic plan view for explaining the structure of a coil component  100   a  according to a modification. 
     The coil component  100   a  illustrated in  FIG. 10  differs from the above-described coil component  100  in that the first coil pattern CP 1  is provided along the outer shape of the fourth coil pattern CP 4  and that the second and third coil patterns CP 2  and CP 3  are partly provided along a part of the first coil pattern CP 1 . More specifically, the sections S 12  and S 13  each include a part whose coordinate in the x-direction changes along the winding direction, and accordingly, the section S 23  of the second coil pattern CP 2  provided along the section S 12  of the first coil pattern CP 1  and the section S 32  of the third coil pattern CP 3  provided along the section S 13  of the first coil pattern CP 1  each have a part whose coordinate in the x-direction changes along the winding direction. As exemplified by the coil component  100   a  of  FIG. 10 , the first coil pattern CP 1  and the second and third coil patterns CP 2  and CP 3  may partly overlap in the y-direction. It follows that the sections S 23  and S 32  of the second and third coil patterns CP 2  and CP 3  partly extend toward the center in the x-direction, thus enhancing antenna characteristics at substantially the center portion in the x-direction. 
       FIG. 11  is a block diagram of a wireless power transmitting device  60  including the coil component  100  according to the present embodiment. 
     The wireless power transmitting device  60  illustrated in  FIG. 11  includes the coil component  100  having the first to fourth coil patterns CP 1  to CP 4 , a communication circuit  61  connected to the first to third coil patterns CP 1  to CP 3 , and a power transmitting circuit  62  connected to the fourth coil pattern CP 4 . The communication circuit  61  and power transmitting circuit  62  are connected to a control circuit  63 . Thus, data transmitted and received through a communication line  64  can be exchanged with the smartphone  3  through the first to third coil patterns CP 1  to CP 3  for NFC, and power supplied from a power supply  65  can be transmitted wirelessly to the smartphone  3  through the fourth coil pattern CP 4  for wireless power transmission. 
     As described above, according to the present embodiment, there can be provided a coil component  100  suitable for a terminal holder  1  capable of performing communication with a mobile terminal through NFC and charging the mobile terminal through wireless power transmission. 
     While the preferred embodiment of the present invention has been described, the present invention is not limited to the above embodiment, and various modifications may be made within the scope of the present invention, and all such modifications are included in the present invention. 
     The technology according to the present disclosure includes the following configuration examples, but not limited thereto. 
     A coil component according to one embodiment of the present disclosure includes a first coil pattern, a second coil pattern connected to the first coil pattern, and a magnetic member covering the first and second coil patterns in the axial direction thereof. The first and second coil patterns are arranged side by side in a first direction perpendicular to the axial direction. The first coil pattern has a first protrusion protruding in a second direction perpendicular to the axial direction and the first direction from a first outer peripheral end of the magnetic member in the second direction. 
     In the coil component, magnetic flux is suppressed from extending in the second direction but correspondingly extends in the first direction, thus efficiently extending the communication coverage area. 
     The second coil pattern may have a second protrusion protruding in the first direction from a second outer peripheral end on one side of the magnetic member in the first direction. With this configuration, outside the second coil pattern, the magnetic flux generated from the first coil pattern and the magnetic flux generated from the second coil pattern are suppressed from weakening each other. 
     The distance between the second protrusion and the second outer peripheral end of the magnetic member in the first direction may be less than ½ of the opening width of the second coil pattern in the first direction. With this configuration, the communication coverage area extends largely in the first direction. 
     The second coil pattern may have a third protrusion protruding in the second direction from the first outer peripheral end of the magnetic member. With this configuration, the magnetic flux is suppressed from extending in the second direction but correspondingly extends sufficiently in the first direction. 
     The first and second coil patterns may partly overlap each other in the second direction. In this case, a first section of the first coil pattern that overlaps the magnetic member may include a part whose coordinate in the first direction changes along the winding direction, and a second section of the second coil pattern may be provided along the first section. With this configuration, antenna characteristics at substantially the center portion in the first direction can be enhanced. 
     The coil component may further include a third coil pattern connected to the first coil pattern, and the first coil pattern may be arranged between the second and third coil patterns. With this configuration, the communication coverage area extends in the first direction. 
     The third coil pattern may have a fourth protrusion protruding in the first direction from a third outer peripheral end on the other side of the magnetic member in the first direction. With this configuration, outside the third coil pattern, the magnetic flux generated from the first coil pattern and the magnetic flux generated from the third coil pattern are suppressed from weakening each other. 
     The distance between the fourth protrusion and the third outer peripheral end of the magnetic member in the first direction may be less than ½ of the opening width of the third coil pattern in the first direction. With this configuration, the communication coverage area extends largely in the first direction. 
     The third coil pattern may have a fifth protrusion protruding in the second direction from the first outer peripheral end of the magnetic member. With this configuration, the magnetic flux is suppressed from extending in the second direction but correspondingly extends sufficiently in the first direction. 
     The first and third coil patterns may partly overlap each other in the second direction. In this case, a third section of the first coil pattern that overlaps the magnetic member may include a part whose coordinate in the first direction changes along the winding direction, and a fourth section of the third coil pattern may be provided along the third section. With this configuration, antenna characteristics at substantially the center portion in the first direction can be enhanced. 
     The first to third coil patterns may be connected such that the magnetic flux generated from the first coil pattern and the magnetic fluxes generated from the second and third coil patterns have mutually opposite phases. With this configuration, the magnetic flux generated from the first coil pattern and the magnetic fluxes generated from the second and third coil patterns mainly strengthen each other. 
     The number of turns of each of the second and third coil patterns may be larger than the number of turns of first coil pattern. With this configuration, antenna characteristics on both sides in the first direction can be enhanced 
     The coil component may further include a fourth coil pattern arranged inside the opening area of the first coil pattern and having the same axial direction as the first coil pattern. In this case, the coil pattern may further include a substrate, and the first, second, and fourth coil patterns may be provided on at least one surface of the substrate. With this configuration, the first, second, and fourth coil patterns can be formed on surfaces of the substrate, thus reducing the number of components. Further, the first, second, and fourth coil patterns can be formed at a time, thus simplifying the production process. 
     A wireless power transmitting device according to the embodiment of the present disclosure includes the coil component described above, a communication circuit connected to the first and second coil patterns, and a power transmitting circuit connected to the fourth coil pattern. 
     With the wireless power transmitting device of the present disclosure, the communication coverage area can be extended efficiently.