This application is based upon and claims the benefit of priority from prior Japanese Patent Applications No. 2005-354239, filed Dec. 8, 2005; and No. 2006-268049, filed Sep. 29, 2006, the entire contents of both of which are incorporated herein by reference.
1. Field of the Invention
This invention relates to an antenna device and electronic equipment comprising the antenna device.
2. Description of the Related Art
As one type of electronic equipment, a radio wave clock is well known. The radio wave clock receives a standard radio wave including time information, and then, automatically corrects a current time. The radio wave clock uses a bar antenna device for receiving the standard radio wave, and the bar antenna device includes a core formed of a magnetic material such as an amorphous metal or ferrite and a coil wound around the core.
The radio wave clock is roughly classified into a wristwatch type and a placement clock type. An outer case of the wristwatch type radio wave clock is small, and thus, the antenna device is severe in dimensional restriction. In a case where the outer case of the wristwatch type radio wave clock is formed of a metal such as stainless or titanium, the metallic case lowers receiving sensitivity of the antenna device.
A structure for improving the receiving sensitivity of the antenna device is disclosed in FIGS. 1, 2, and 4 of Jpn. Pat. Appln. KOKAI Publication No. 2004-274609. In this conventional antenna device, a core is formed by laminating a plurality of sheet plates formed of a magnetic material such as an amorphous metal. A laminated core includes a coil winding portion around which a coil is wound, and a pair of coil non-winding portions which protrude from both ends of the coil winding portion and around which a coil is not wound. Spacers are inserted into the plurality of sheet plates at each of the coil non-winding portions to make the thickness of each of the coil non-winding portions being greater than that of the coil winding portion. However, a work of inserting the spacers into the plurality of sheet plates at each of the coil non-winding portions is complicated and increases manufacturing cost of this conventional antenna device. In addition, the antenna device that increases the thickness of each of the coil non-winding portions more greatly than that of the coil winding portion prevents the thickness of the outer case of the wristwatch type radio wave clock using such an antenna device from decreasing.
An antenna device according to one aspect of the present invention is installed in a case of an electronic equipment, the case including a housing space for housing the antenna device and a surface in which an aperture is formed, the aperture allowing access from an external space to the housing space. The antenna device comprises a magnetic substance and a coil wound around the magnetic substance. The magnetic substance includes a coil winding portion, around which the coil is wound, and a pair of coil non-winding portions, which protrude from both ends of the coil winding portion, around each of which the coil is not wound, and which are magnetically coupled with the coil winding portion. And, at least one of the coil non-winding portions is curved in an arc shape toward a distal end thereof from a base thereof so as to extend along an inner peripheral surface of the housing space when the antenna device is housed in the housing space and is viewed from the surface of the case.
An electronic equipment according to one aspect of the present invention comprises: a case including a housing space and a surface in which an aperture is formed, the aperture allowing access from an external space to the housing space; the above described antenna device being housed in the housing space of the case; an electric circuit unit housed in the housing space of the case, electrically connected to the antenna device, and controlled on a basis of a signal inputted from the antenna device; and a decorative plate closing the aperture.
An electronic equipment according to another aspect of the present invention comprises: a case including a housing space and a surface in which an aperture is formed, the aperture allowing access from an external space to the housing space; the above described antenna device being housed in the housing space of the case; an electric circuit unit housed in the housing space of the case, electrically connected to the antenna device, and controlled on a basis of a signal inputted from the antenna device; and a decorative plate closing the aperture. The pair of coil non-winding portions of the magnetic substance comprises thin film shaped magnetic members provided on an inner surface of the decorative plate.
Additional objects and advantages of the invention will be set forth in the description of the which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objects and advantages of the invention may be realized and obtained by means of the instrumentalities and combinations particularly pointed out herein after.
The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention, and together with the general description given above and the detailed description of the embodiments given below, serve to explain the principles of the invention.
An electronic equipment 10 shown in
A pair of band attaching portions 24 are formed on two regions (a 12 o'clock direction region and a 6 o'clock direction region) that are fairly opposite to each other on an external periphery of the case 20, and both ends 22 of one watch band or proximal ends of a pair of watch bands are removably attached to the band attaching portions 24.
Each band attaching portion 24 protrudes outwardly from the external periphery of the case 20 in a radial direction of the case 20. An attaching hole 28 is formed at a protruding end portion of each of the band mounting portions 24, and a band attaching pin 26 inserted into each of the both ends 22 of the one watch band is removably attached in the attaching hole 28.
A plurality of switches 30 are mounted on the outer periphery of the case 20. The plurality of switches 30 are electrically connected to the electric circuit unit 12 in the housing space 14 of the case 20 so that an operation of the electric circuit unit 12 is controlled by operating each of the switches 30. That is, any of a plurality of functions preset in the electric circuit unit 12 can be performed.
A watch glass 32 is mounted on the surface 18 of the case 20 via a packing 34 and covers the aperture 16. In the present embodiment, a back aperture 36 is formed in a back surface of the case 20, and the back aperture 36 allows access from an external space to the housing space 14. The back aperture 36 is covered with a back cap 40 via a packing 38. The back cap 40 is formed of a metal such as stainless or titanium, for example.
An antenna device 42, a battery serving as a drive source for the electric circuit unit 12, and a well known analog hand moving mechanism 43 are also housed in the housing space 14 of the case 20, and an operation of the analog hand moving mechanism 43 is controlled by the electric circuit unit 12. The antenna device 42, the battery, and the analog hand moving mechanism 43, together with the electric circuit unit 12, configure a watch module 44.
The antenna device 42 is electrically connected to the electric circuit unit 12, and an operation of the electric circuit unit 12 is controlled on a basis of a signal received by the antenna device 42.
A decorative plate 45 closes the aperture 16 of the surface 18 of the case 20 between the watch glass 32 and the watch module 44. In the present embodiment, the decorative plate 45 is configured as a dial plate, and the analog hand moving mechanism 43 includes three concentrically arranged indicator shafts 46 penetrating the decorative plate 45. An hour hand 48a, a minutes hand 48b, and a second hand 48c are attached on the distal ends of the three indicator shafts 46.
The electric circuit unit 12 includes a control IC 50 like a central processing unit (CPU), an oscillation circuit portion 52, a time counting circuit portion 54 connected to the oscillation circuit portion 52, an input portion 56, a display portion 58, a ROM 60, a RAM 62, and a receiving control circuit portion 64 electrically connected to the antenna device 42. And, the time counting circuit portion 54, the input portion 56, the display portion 58; the ROM 60, the RAM 62, and the receiving control circuit portion 64 are electrically connected to the CPU 50.
The oscillation circuit portion 52 always outputs a clock signal of a predetermined frequency. The time counting circuit portion 54 calculates a current time based on the clock signal outputted from the oscillation circuit portion 52, and then outputs current time data to the CPU 50. The input portion 56 includes the plurality of switches 30. The display portion 58 includes a screen exposed in a part of the decorative plate 44. The ROM 60 stores a plurality of system programs, application programs, or data and the like, relating to an operation of the electronic equipment 10. The RAM 62 is used as a work area of the CPU 50, and temporarily stores the programs or data read out from the ROM 60 and the data or the like processed by the CPU 50. The receiving control circuit portion 64 cuts an unnecessary frequency component from a standard time signal received by the antenna device 42 to take out a predetermined frequency signal (time code of standard time), then converts the predetermined frequency signal into a corresponding electronic signal, and output the converted electrical signal to the CPU 50.
A not shown motor serving as a drive source for the analog hand moving mechanism 43 is further electrically connected to the CPU 50.
The CPU 50 reads out any of the plurality of programs stored in the ROM 400 in response to a predetermined timing or an operating signal inputted from any switch 30 of the input portion 56, expands the read out program on the RAM 500, and carries out commanding, data transfer and the like to the analog hand moving mechanism 43, the display portion 58, the time counting circuit portion 54, and the receiving control circuit portion 54, based on the read out program. Specifically, the CPU 50 controls the receiving control circuit portion 64 at every predetermined times, for example, and makes the receiving control circuit portion 64 receive the standard time radio wave including the time code of the standard time via the antenna device 42. Then, the CPU 50 corrects the current time data calculated by the time counting circuit portion 54 based on this receiving signal, makes the analog hand moving mechanism 43 indicate the current time calculated and corrected by the time counting circuit portion 54, and further makes the display portion 58 display the current time.
Now, a configuration of the antenna device 42 will be described with reference to
At least one, each of the both in this embodiment, of the pair of coil non-winding portions 72 is curved in an arc shape from a base thereof to a distal end thereof so as to extend along an internal periphery of the housing space 14 of the case 20.
The magnetic substance 66 includes a core member that contains the coil winding portion 70 and the pair of coil non-winding portions 72, and the core member is a laminated core member structured by laminating a plurality of sheet plates of magnetic material like an amorphous metal one another. The plurality of sheet plates of the laminated core member are classified into two types of groups, one of which is a short piece 74 and another of which is a long piece 76 that is longer than the short piece 74.
Both end portions of the short piece 74 correspond to the pair of coil non-winding portions 72 and a center portion of the short piece 74 corresponds to the coil winding portion 70, as viewed from the surface 18 of the case 20. The width of each of the both end portions of the short piece 74 is so set that it is larger than that of the center portion thereof. A side edge of each of the both end portions, facing the inner periphery of the housing space 14 of the case 20, is curved along the inner periphery.
Both end portions of the long piece 76 also correspond to the pair of coil non-winding portions 72 and a center portion of the long piece 76 also corresponds to the coil winding portion 70, as viewed from the surface 18 of the case 20. The width of each of the both end portions of the long piece 74 is so set that it is the same as that of the center portion thereof. Each of the both end portions of the long piece 76 is curved along the inner periphery of the housing space 14 of the case 20.
In the laminated core member of the magnetic substance 66, a first group including the plurality of laminated short pieces 74 is located near to the back cap 40 and a second group including the plurality of laminated long pieces 76 is located near to the decorative plate 45. With this location, a length of each one of the groups decreases in a stepwise manner from the second group (the laminated long pieces 76) that is the closest to the surface 18 of the case 20 to the first group (the laminated short pieces 74) that is the most distant from the surface 18 of the case 20, in the laminated core member of the magnetic substance 66 along a depth direction D of the housing space 14.
In addition, as viewed from the surface 18 of the case 20, in each of the coil non-winding portions 72 of the laminated core member of the magnetic substance 66, a width of a distal end region of each of the coil non-winding portions 72, which is distant from each of the both ends of the coil winding portion 70, (a width of a distal end region of each of the both end portions of the laminated long pieces 76 of the second group in the present embodiment) is smaller than that of a base region of each of the coil non-winding portions 72, which is close to each of the both ends of the coil winding portion 70, (a width of a combination of a base region of each of the both end portions of the laminated long pieces 76 of the second group and each of the both end portions of the laminated short pieces 74 of the first group in the present embodiment).
Further, in each of the coil non-winding portions 72 of the laminated core member of the magnetic substance 66, a dimension taken along a depth direction D of the housing space 14 in the distal end region of each of the coil non-winding portions 72, which is distant from each of the both ends of the coil winding portion 70, (a dimension taken along the depth direction D of the housing space 14 in a distal end region of each of the both end portions of the laminated long pieces 76 of the second group in the present embodiment) is smaller than that of a base region of each of the coil non-winding portions 72, which is close to each of the both ends of the coil winding portion 70, (a dimension taken along the depth direction D of the housing space 14 in a combination of a base region of each of the both end portions of the laminated long pieces 76 of the second group and each of the both end portions of the laminated short pieces 74 of the first group in the present embodiment).
The laminated core member of the magnetic substance 66 is housed in a core case 78 of synthetic resin. The core case 78 includes a main body 78a and a cover 78b. The main body 78a has an opening to expose a surface of the laminated core member, which is the closest to the surface 18 of the case 20, and the cover 78b covers the aperture of the main body 78a.
A pair of outward flanges 78c are formed at longitudinal both ends of a portion on an outer surface of the core case 78, the portion corresponding to the center portion of the laminated core member, and a lead wire is wound on the portion of the outer surface of the core case 78 between the outer flanges 78c and configures a coil 68.
The pair of coil non-winding portions 72 of the laminated core member of the magnetic substance 66 includes a pair of foil elements 80 each of which protrudes in an outer direction from each of the both ends of the coil winding portion 70 of the laminated core member. Each foil element 80 is formed of a material having a magnetic permeability that is smaller than that of the laminated core member of the magnetic substance 66. In the present embodiment, the foil member is formed of an amorphous metal having a thickness of 16 μm.
The foil elements 80 are magnetically coupled to the both ends of the coil winding portion 70 of the laminated core member. The term “magnetically coupled” used here includes a case in which one magnetic member (the foil 80 in the present embodiment) and the other magnetic member (the coil winding portion 70 of the laminated core member in the present embodiment) are directly connected to each other so that magnetism passes through these magnetic members, of course, and a case in which one magnetic member (the foil 80 in the present embodiment) and the other magnetic member (the coil winding portion 70 of the laminated core member in the present embodiment) are faced each other with a gap therebetween so that magnetism passes through these magnetic members via the gap.
In the present embodiment, the foil elements 80 are adhered by adhesive onto outer surfaces of longitudinal both end portions of the core case 78, corresponding to the coil non-winding portions 72 of the laminated core member of the magnetic substance 66. More specifically, the foil elements 80 are adhered to outer surfaces of longitudinal both end portions of the cover 78b of the core case 78, and extend along the extending directions of the coil non-winding portions 72.
When the antenna device 42 is placed in a magnetic field of a standard time radio wave (hereinafter, referred to as a “signal magnetic field”), the signal magnetic filed acts to the antenna device 42 as follows. The standard time radio wave is a long wave having a wavelength of several kilometers, and the magnetic field may be regarded as a parallel magnetic field in which magnitude of each component of the magnetic field does not change at arbitrary location in the dimensional range of the antenna device 42.
When the magnetic substance 66 is placed in the signal magnetic field to arrange a center line of the coil 68 in parallel to the direction of the signal magnetic field, a magnetic flux of the signal magnetic field (hereinafter, referred to as a “signal magnetic flux”) concentrates at the magnetic substance 66 having magnetic permeability higher than that of an space surrounding the magnetic substance 66. As a result, the signal magnetic flux and the coil 68 cross each other, and an inductive electromotive force V is generated in the coil 68 such that a magnetic flux is generated in a direction that can prevent a change of the signal magnetic flux inside the coil 68 in accordance with a Lenz's law. And, since the signal magnetic field as an alternating magnetic field cyclically changes magnitude and direction of the signal magnetic flux, the inductive electromotive force V is an alternative electric force. As a result, at the magnetic substance 66 as well, an alternative magnetic field is generated such that the size or direction of the magnetic flux cyclically changes in accordance with a time based change of the signal magnetic flux.
The inductive electromotive force V generated in the coil 68 is detected by the receiving control circuit portion 64 (refer to
In general, a magnetic flux is distributed so that a magnetic resistance becomes as small as possible. Therefore, the signal magnetic flux passes through the pair of foil elements 80 each having higher magnetic permeability than air, or alternatively, is attracted to the foil elements 80. Further, the signal magnetic flux is attracted to the laminated core member having higher magnetic permeability than that of each foil element 80, and passes through the laminated core member. Namely, in a case where the pair of foil elements 80 are provided at both ends of the coil winding portion 70 of the laminated core member, more signal magnetic fluxes pass through the laminated core member as compared with a case in which the pair of foil elements 80 are not provided. As a result, the inductive electromotive force V generated in the coil 68 increases, and the receiving sensitivity of the antenna device 42 is improved.
In addition, where the pair of foil elements 80 are provided at the both ends of the coil winding portion 70 of the laminated core member, the signal magnetic flux can flow in the laminated core member more easily. Thus, the effective magnetic permeability of the magnetic substance 66 rises, and its resonance frequency is lowered. This is because an inductance L is increased by rise of the effective magnetic permeability.
f=1/2Π(LC)1/2 (Formula 1)
As shown in (formula 1), a resonance frequency f is reduced as the inductance L increases.
As shown in
[First Modification of the Antenna Device 42]
Structural members of the first modification of the antenna device 42 are the same as those of the antenna device 42. Therefore, in the first modification shown in
The first modification is different from the antenna device 42 in that the pair of foil elements 80 are adhered to regions on the outer surfaces of the longitudinal both end portions of the main body 78a of the core case 78, the regions corresponding to the longitudinal both end portions of the plurality of short pieces 74 of the first group in the laminated core member of the magnetic substance 66 and facing the back cover 40, and the pair of foil elements 80 extend along the extending directions of the pair of coil non-winding portions 72 of the laminated core member of the magnetic substance 66.
[Second Modification of the Antenna Device 42]
Structural members of the second modification of the antenna device 42 are the same as those of the antenna device 42. Therefore, in the second modification shown in
The second modification is different from the antenna device 42 in that the pair of foil elements 80 are adhered to regions on the outer surfaces of the longitudinal both end portions of the main body 78a of the core case 78, the regions corresponding to the longitudinal both end portions of the plurality of long pieces 76 of the second group in the laminated core member of the magnetic substance 66 and facing the back cover 40, and the pair of foil elements 80 extend along the extending directions of the pair of coil non-winding portions 72 of the laminated core member of the magnetic substance 66.
[Third Modification of the Antenna Device 42]
Structural members of the third modification of the antenna device 42 are the same as those of the antenna device 42. Therefore, in the third modification shown in
The third modification is different from the antenna device 42 in that the pair of foil elements 80 are adhered to regions on the outer surfaces of the longitudinal both end portions of the main body 78a of the core case 78, the regions facing the inner periphery of the housing space 14, and the pair of foil elements 80 extend along the extending directions of the pair of coil non-winding portions 72 of the laminated core member of the magnetic substance 66.
[Relationship Between Attaching Positions and the Number of the Foil Elements 80 Attached and Receiving Performance in the Antenna Device 42]
In the case (A), as shown in
In the case (B), three foil elements 80, instead of one, are adhered to each of the same regions on the outer surface of the both longitudinal end portions of the main body 78a of the core case 78 in the case (A).
In the case (C): as shown in
In the case (D), in addition to the case (C), two foil elements 80, instead of one, are adhered to each of the same regions on the outer surface of the both longitudinal end portions of the main body 78a of the core case 78 as shown in
In any of the cases (A) to (D), a receiving voltage rises as compared with the case in which the foil elements 80 are not adhered. That is, the receiving sensitivity of the antenna device 42 having at least a pair of foil elements 80 magnetically coupled with the both ends of the laminated core member of the magnetic substance 66 is improved in comparison with that of the antenna device having the same configuration as the antenna device 42, excepting that the foil elements 80 are not magnetically coupled.
In comparison between the case (A) and the case (B), the rise of the receiving voltage in the case (B) is more remarkable than that in the case (A). In comparison between the case (B) and the case (C), the rise of the receiving voltage in the case (C) is more remarkable that that in the case (B). Further, in comparison between the case (C) and the case (D), the rise of the receiving voltage in the case (D) is more remarkable than that in the case (C).
That is, the receiving sensitivity of the antenna device 42 can be improved by increasing the number of foil elements 80 to be adhered and the number of positions to which the foil elements 80 are to be adhered.
[Second Antenna Device]
Now, a second antenna device 82 that can be used in the electronic equipment 10 shown in
Structural members of the second antenna device 82 are the same as those of the first antenna device 42 described above with reference to
The second antenna device 82 is different from the first antenna device 42 in a structure of a core case 84 for housing the laminated core member of the magnetic substance 66.
The core case 84 is formed of a synthetic resin, and includes a main body 84a and a cover 84b. The main body 84a houses the laminated core member and has an aperture exposing a surface of the laminated core member, the surface being the closest to the surface 18 of the case 20, and the cover 84b closes the aperture.
A pair of outward flanges 84a are formed at both longitudinal ends of a portion on the outer surface of the core case 84, the portion corresponding to the center portion of the laminated core member, and a lead wire is wound on the center portion of the outer surface of the core case 84 between the pair of outward flanges 84c, thereby configuring a coil 68.
Each portion of the core case 84, which houses each of the both end portions of the laminated core member, i.e., each of the pair of coil non-winding portions 72 of the magnetic substance 66, produces a first gap 86a to a region at each of the both longitudinal end portions of the plurality of long pieces 76 in the second group of the laminated core members, that region facing the decorative plate 45. The above described each portion of the core case 84 also produces a second gap 86b to a region at each of the both longitudinal end portions of the plurality of long pieces 76 in the second group of the laminated core members, that region facing the back cover 40. The above described each portion of the core case 84 further produces a third gap 86c to a region at each of the both longitudinal end portions of the plurality of short pieces 74 in the first group of the laminated core members, that region facing the back cover 40.
Further, slits 88a, 88b, and 88c are formed at positions on each of the both longitudinal end portions of the core case 84, the positions corresponding to the first gap 86a, the second gap 86b, and the third gap 86c. These slits 88a, 88b, and 88c allow access to the first gap 86a, the second gap 86b, and the third gap 86c from an external space.
Foil elements 80 are inserted into the first gap 86a, the second gap 86b, and the third gap 86c at each of the both longitudinal end portions of the core case 84 through these slits 88a, 88b, and 88c.
The foil element 80 inserted into the first gap 86a is magnetically connected to the region of each of the both longitudinal end portions of the plurality of long pieces 76 in the second group of the laminated core members in the core case 84, the region facing the decorative plate 45.
The foil element 80 inserted into the second gap 86b is magnetically connected to the region of each of the both longitudinal end portions of the plurality of long pieces 76 in the second group of the laminated core members in the core case 84, the region facing the back cover 40.
The foil element 80 inserted into the third gap 86c is magnetically connected to the region of each of the both longitudinal end portions of the plurality of short pieces 74 in the first group of the laminated core members in the core case 84, the region facing the back cover 40.
The number of foil elements 80 inserted into each of the first gap 86a, the second gap 86b, and the third gap 86c through each of the slits 88a, 88b, and 88c can be set in a range between one and plural in relation to the thickness of the foil element 80, the height of each of the slits 88a, 88b, and 88c, and the height of each of the first gap 86a, the second gap 86b, and the third gap 86c.
[Third Antenna Device]
Now, a third antenna device 92 that can be used in the electronic equipment 10 shown in
Structural members of the third antenna device 92 are the same as those of the first antenna device 42 described above with reference to
The third antenna device 92 is different from the first antenna device 42 in that the core case 78 is omitted. The coil 68 is wound around the outer surface of the coil winding portion 70 at the center portion of the laminated core member of the magnetic substance 66. And, a pair of foil elements 80 is adhered to a pair of regions on the pair of coil non-winding portions 72 at the both longitudinal end portions of the laminated core member of the magnetic substance, the regions facing the decorative plate 45. That is, the pair of foil elements 80 is adhered to a pair of regions on the both longitudinal end portions of the plurality of long pieces 76 of the second group in the laminated core member, the regions facing the decorative plate 45. The pair of foil elements 80 extend along the extending directions of the pair of coil non-winding portions 72.
[First to Third Modifications of the Third Antenna Device 92]
Now, first to third modifications of the third antenna device 92, each of which can be used in the electronic equipment 10 shown in
Structural members of each of the first to third modifications of the third antenna device 92 are the same as those of the first antenna device 42 described above with reference to
The first modification of the third antenna device 92 is different from the third antenna device 92 in that, as indicated by a solid line in
The second modification of the third antenna device 92 is different from the third antenna device 92 in that, as indicated by a two-dots chain line in
The third modification of the third antenna device 92 is different from the third antenna device 92 in that, as indicated by a solid line in
[Fourth Antenna Device]
A fourth antenna device 102 that can be used in the electronic equipment 10 shown in
Structural members of the fourth antenna device 102 are the same as those of the first antenna device 42 described above with reference to
The fourth antenna device 102 is different from the first antenna device 42 in that the core case 78 is omitted. The coil 68 is wound around the outer surface of the coil winding portion 70 at the center portion of the laminated core member of the magnetic substance 66. The laminated core member is configured by laminating a plurality of sheet plates 104 formed of magnetic material such as an amorphous metal, the sheet plates having different lengths from each other. In the plurality of sheet plates 104 of the laminated core member, the shortest sheet plate 104 is located to be the closest to the back cover 40, and the plurality of sheet plates 104 are laminated so as to be sequentially longer as they approach the decorative plate 45.
Further, the pair of coil non-winding portions 72 at the both end portions of the magnetic substance 66, i.e., the both end portions of the plurality of sheet plates 104 in the laminated core member, are bend so that their distal end regions which are distant from the coil winding portions 70 at the center portion of the magnetic substance 66 are located nearer to the decorative plate 45, i.e., the aperture 16 (refer to
In this vending, the receiving sensitivity of the fourth antenna device 102 can be improved more remarkably.
The both end portions of the longest sheet plate 104 that is the closest to the decorative plate 45 in the laminated core member may be brought into contact with or may be adhered to the inner surface of the decorative plate 45, as shown in
With this configuration, a surface area of the magnetic substance 66 can be increased without substantially increasing a capacity occupied by the fourth antenna device 102 in the housing space 14 of the case 20, and as a result, the receiving sensitivity of the fourth antenna device 102 can be improved more remarkably.
Further, in the fourth antenna device 102, each of the pair of coil non-winding portions 72 at the both end portions of the magnetic substance 66 is shaped so that the width of each of the distal end regions of the pair of coil non-winding portions 72, the distal end regions being distant from the coil winding portion 70 at the center portion of the magnetic substance 66, is smaller than the width of each of the base regions of the pair of coil non-winding portions 72, the base regions being close to the coil winding portion 70 at the center portion of the magnetic substance 66, when viewed from the surface 18 of the case 20.
Further, with this configuration, the capacity occupied by the fourth antenna device 102 in the housing space 14 of the case 20 can be reduced more remarkably.
[Fifth Antenna Device]
A fifth antenna device 106 that can be used in the electronic equipment 10 shown in
Structural members of the fifth antenna device 106 are the same as those of the first antenna device 42 described above with reference to
The fifth antenna device 106 is different from the first antenna device 42 in that the core case 78 is omitted. The coil 68 is wound around the outer surface of the coil winding portion 70 at the center portion of the laminated core member of the magnetic substance 66. And, the laminated core member is configured by laminating a plurality of sheet plates 104 formed of a magnetic material such as an amorphous metal, the sheet plates having different lengths from each other. In the plurality of sheet plates 104 of the laminated core member, the shortest sheet plate 104 is located to be the closest to the back cover 40, and the plurality of sheet plates 104 are laminated so as to be sequentially longer as they approach the decorative plate 45.
Further, the pair of coil non-winding portions 72 at the both end portions of the magnetic substance 66, i.e., the both end portions of the plurality of sheet plates 104 in the laminated core member, are bend so that the distal end regions of the pair of coil non-winding portions 72, the distal end regions being distant from the coil winding portion 70 at the center portion of the magnetic substance 66 are located nearer to the decorative plate 45 than the base regions of the pair of coil non-winding portions 72, the base regions being close to the coil winding portion 70 at the center portion of the magnetic substance 66.
With this configuration, the receiving sensitivity of the fifth antenna device 106 can be improved more remarkably.
The pair of coil non-winding portions 72 at the both end portions of the magnetic substance 66 comprises a pair of thin film shaped magnetic members 108 provided on the inner surface of the decorative plate 45 on extending lines of the distal ends of the pair of coil non-winding portions 72. The pair of thin film shaped magnetic members 108 can be formed by adhering a thin film formed of magnetic material such as an amorphous metal, onto the inner surface of the decorative plate 45, by using a variety of publicly known methods, or by coating powders of magnetic material.
The distal ends of the pair of coil non-winding portions 72, i.e., the both ends of the longest sheet plate 104 that is the closest to the decorative plate 45 in the laminated core member are magnetically coupled with the pair of thin film shaped magnetic members 108 by adhesive 110 having magnetic property. The adhesive 110 having magnetic property can be provided, for example by mixing powders of a magnetic substance with usual adhesive that does not have magnetic property.
With this configuration, a surface area of the magnetic element 66 can be increased without substantially increasing a capacity occupied by the fifth antenna device 106 in the housing space 14 of the case 20, and as a result, the receiving sensitivity of the fifth antenna device 106 can be improved more remarkably.
Moreover, the electronic equipment 10 using the fifth antenna device 106 can be easily manufactured. This is because, in a process for manufacturing this electronic equipment 10, the fifth antenna device 106 can be installed to a predetermined location in the housing space 14 of the case 20 while the length of the fifth antenna device 106 is reduced by removing the thin film shaped magnetic member 108 from the magnetic element 66.
For example, the pair of thin film shaped magnetic members 108 are provided in advance at predetermined positions on the inner surface of the decorative plate 45. The fifth antenna device 106 from which the pair of thin film shaped magnetic members 108 are omitted is installed at a predetermined position in the housing space 14 of the case 20. Further, the adhesive 110 having magnetic property is applied to the regions at distal ends of the pair of coil non-winding portions 72, i.e., at the both ends of the longest sheet plate 104 that is the closest to the decorative plate 45 in the laminated core member, the regions facing the decorative plate 45. Alternatively, the adhesive 110 having magnetic property is applied to predetermined regions of the pair of the thin film shaped magnetic members 108. Next, the decorative plate 45 is located at a predetermined position in the aperture 16 of the housing space 14 of the case 20 so that the predetermined regions of the pair of thin film shaped magnetic members 108 on the inner surface of the decorative plate 45 are abutted against the decorative plate facing regions on the distal ends of the pair of coil non-winding portions 72, i.e., the decorative plate facing regions on the both ends of the longest sheet plate 104 that is the closest to the decorative plate 45 in the laminated core member, via the adhesive 110 having magnetic property.
[Sixth Antenna Device]
Now, a sixth antenna device 112 that can be used in the electronic equipment 10 shown in
Structural members of the sixth antenna device 112 are the same as those of the first antenna device 42 described above with reference to
The sixth antenna device 112 is different from the first antenna device 42 in that the core case 78 is omitted. The coil 68 is wound around the outer surface of the coil winding portion 70 at the center portion of the laminated core member of the magnetic substance 66. In addition, the laminated core member is configured by laminating a plurality of short pieces 74 formed of magnetic material such as an amorphous metal, and the lengths of the short pieces 74 are the same as to each other.
Further, the pair of coil non-winding portions 72 at the both end portions of the magnetic substance 66, i.e., the both end portions of the plurality of short pieces 74 in the laminated core member, are bend so that the distal end regions of the pair of coil non-winding portions 72, the distal end regions being distant from the coil winding portion 70 at the center portion of the magnetic substance 66, is located nearer to the decorative plate 45 than the base regions of the pair of coil non-winding portions 72, the base regions being close to the coil winding portion 70 at the center portion of the magnetic substance 66.
With this configuration, the receiving sensitivity of the sixth antenna device 112 can be improved more remarkably.
The pair of coil non-winding portions 72 at the both end portions of the magnetic substance 66 comprises a pair of thin film shaped magnetic members 114 provided on the inner surface of the decorative plate 45 on the extending lines of the distal ends of the pair of coil non-winding portions 72. The pair of thin film shaped magnetic members 114 can be formed by adhering thin films formed of magnetic material such as an amorphous metal onto the inner surface of the decorative plate 45, by using a variety of publicly known methods, or by coating powders of magnetic material.
And, the distal ends of the pair of coil non-winding portions 72, i.e., the both ends of the short piece 74 that is the closest to the decorative plate 45 in the laminated core member, are magnetically coupled with the pair of thin film shaped magnetic members 114 by magnetic spacers 116. The magnetic spacers 116 are formed of material having magnetic property such as an amorphous metal, a ferrite, or permalloy, for example.
The magnetic spacer 116 is adhered to one or both of the distal end of the corresponding coil non-winding portion 72, i.e., the distal end of the corresponding the short piece 74 that is the closest to the decorative plate 45 in the laminated core member, and the corresponding thin film shaped magnetic member 114.
With this configuration, the surface area of the magnetic substance 66 can be increased without substantially increasing the capacity occupied by the sixth antenna device 112 in the housing space 14 of the case 20, and as a result, the receiving sensitivity of the sixth antenna device 112 can be improved more remarkably.
Moreover, the electronic equipment 10 using the sixth antenna device 112 can be easily manufactured. This is because, in a process for manufacturing this electronic equipment 10, the sixth antenna device 112 can be installed at the predetermined position in the housing space 14 of the case 20 while the length of the sixth antenna device 112 is reduced by removing the thin film shaped magnetic members 114 from the magnetic substance 66.
For example, the pair of thin film shaped magnetic members 114 are provided in advance at the predetermined positions on the inner surface of the decorative plate 45. The sixth antenna device 112 from which the pair of thin film shaped magnetic members 114 are removed is installed at the predetermined position in the housing space 14 of the case 20. Further, the magnetic spacers 116 are adhered to the decorative plate facing regions at the distal ends of the pair of coil non-winding portions 72, i.e., the both ends of the short piece 74 that is the closest to the decorative plate 45 in the laminated core member. Alternatively, the magnetic spacers 116 are adhered to the predetermined regions of the pair of thin film shaped magnetic members 114. Next, the decorative plate 45 is located at the predetermined position in the aperture 16 of the housing space 14 of the case 20 so that the predetermined regions of the pair of thin film shaped magnetic members 114 on the inner surface of the decorative plate 45 are abutted against the decorative plate facing regions on the distal ends of the pair of coil non-winding portions 72, i.e., the both ends of the short piece 74 that is the closest to the decorative plate 45 in the laminated core member, via the magnetic spacers 116.
[Modification of Each of the Second to Sixth Antenna Devices 82, 92, 102, 106, and 112]
In each of the second to sixth antenna devices 82, 92, 102, 106, and 112 described above, the coil 68 is directly wound around the coil winding portion 70 at the center portion of the magnetic substance 66. However, the coil winding portion 70 may be covered with a cover formed of material having magnetic permeability such as synthetic resin, and the coil 68 may be wound around this cover.
[Modification of the Magnetic Substance 66]
The magnetic substance 66 of each of the second to sixth antenna devices 82, 92, 102, 106, and 112 described above includes the laminated core member. However, the magnetic substance 66 may be a core member integrally molded with material having magnetic property such as amorphous metal, a ferrite, or permalloy, for example.
Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.
Number | Date | Country | Kind |
---|---|---|---|
2005-354239 | Dec 2005 | JP | national |
2006-268049 | Sep 2006 | JP | national |
Number | Name | Date | Kind |
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6134188 | Ganter et al. | Oct 2000 | A |
7061439 | Minami et al. | Jun 2006 | B1 |
20060214866 | Araki et al. | Sep 2006 | A1 |
Number | Date | Country |
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2004-274609 | Sep 2004 | JP |
Number | Date | Country | |
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20070132648 A1 | Jun 2007 | US |