JP2007151154A - Multiaxial antenna chip - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a multiaxial antenna chip which can be reduced in size. <P>SOLUTION: An X-axis coil portion 73a and a Y-axis coil portion 73b are formed by winding electric wires, respectively around two core pieces each comprised of a magnetic substance, and these two core pieces 72, 72 are disposed approximately in a cross shape, thereby providing an XY-axis antenna. This XY-axis antenna is accommodated in an approximately cross-shaped housing recess 85 corresponding to the outside shape of the relevant XY-axis antenna provided on diagonal lines of a rectangular casing integrally formed from a synthetic resin material. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a chip multi-axis antenna used by being mounted on a circuit board or the like.

In recent years, various remote control devices such as smart entry devices and smart ignition devices have been used in vehicles.
For example, as shown in FIG. 22, the remote control device includes a portable device 101 that performs mutual communication with a transmission / reception device provided in a vehicle. The portable device 101 is owned by a vehicle user (owner). In addition, a uniaxial antenna 102 that exchanges radio waves with a transmission / reception device is mounted in the portable device 101.

  By the way, since the present portable device 101 is bulky, further downsizing is required. However, even if it is attempted to reduce the size of the portable device 101, it is difficult to reduce the size of components such as the mechanical key 103 that have been conventionally used. Therefore, for example, it is conceivable to reduce the size of electrical components such as the uniaxial antenna 102.

  However, a plurality of (two in FIG. 22) uniaxial antennas 102 are provided in portable device 101 in order to reliably receive radio waves from multiple directions, and are arranged in different directions. As a result, a space for mounting two uniaxial antennas 102 in the portable device 101 must be secured, and there is a problem that the entire portable device 101 is increased in size.

  In this case, since the uniaxial antenna 102 is separately mounted on the circuit board 104, there is a possibility that the directivity may be deteriorated when the uniaxial antenna 102 is displaced from each other.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a chip multi-axis antenna that can be miniaturized.

  In order to achieve the above object, according to the first aspect of the present invention, an X-Y winding portion is formed by winding an electric wire around a substantially cross-shaped core made of a magnetic material to form an X-axis winding portion and a Y-axis winding portion. An X-axis winding part and a Y-axis winding part are formed by winding an electric wire around two core pieces made of a magnetic material as an axial antenna, and arranging these two core pieces in a substantially cross shape. The X-Y axis antenna is substantially cross-shaped corresponding to the outer shape of the X-Y axis antenna provided on the diagonal line of the casing integrally formed in a rectangular shape by a synthetic tree material. It is summarized that it is housed in a concave portion.

  According to the present invention, the chip multi-axis antenna has the same function as two single-axis antennas arranged in different directions. As a result, the mounting space for the chip multi-axis antenna can be reduced from the mounting space for two single-axis antennas. That is, the chip multi-axis antenna can be downsized, and the chip multi-axis antenna can be easily mounted.

  According to a second aspect of the present invention, in the chip multi-axis antenna according to the first aspect, in the chip multi-axis antenna according to the first aspect, a wound recess (86) is continuously provided on the outer peripheral surface of the casing. The gist of the present invention is to form a Z-axis antenna by winding a wire around the wound recess to form a Z-axis winding portion.

  According to the present invention, the chip triaxial antenna has the same function as three uniaxial antennas arranged in different directions. As a result, the mounting space for the chip triaxial antenna can be reduced from the mounting space for three uniaxial antennas. That is, the chip triaxial antenna can be downsized, and the chip triaxial antenna can be easily mounted. In addition, since the winding recess is provided in the casing, the Z-axis winding portion can be easily formed.

  According to a third aspect of the present invention, in the chip multi-axis antenna according to the first or second aspect, an X-axis winding portion and a Y-axis winding are obtained by winding an electric wire around two core pieces made of a magnetic material. And forming the X-Y axis antenna by superimposing these two core pieces in a substantially cross shape at the center part of each other, and the recess is formed by the X axis winding part or the Y axis winding. A first recess corresponding to the outer shape of one core piece formed with the line portion, and a second corresponding to the outer shape of the other core piece formed with the Y-axis winding portion or the X-axis winding portion. The first recess is formed at a depth corresponding to the thickness of the central portion of the two core pieces superimposed in a substantially cross shape, and on the opening side of the first recess, The second recess has a depth corresponding to the thickness of the other core piece. To become formed in the gist thereof.

  According to the present invention, one core piece formed with the X-axis winding portion or the Y-axis winding portion is formed in the first recess, and the Y-axis winding portion or the X-axis winding is formed in the second recess. The other core piece in which the line part is formed is accommodated. For this reason, two core pieces are suitably accommodated in a recessed part in the state piled up in the substantially cross shape in the center part of each other.

  According to the present invention, the chip multi-axis antenna can be downsized, and the chip multi-axis antenna can be easily mounted.

(First embodiment)
A first embodiment of the present invention will be described below with reference to FIGS.
As shown in FIG. 1, the vehicle remote control device 11 includes a transmission / reception device 13 provided on the vehicle side and a portable device 12 possessed by a user.

  The transmission / reception device 13 includes a transmission circuit 31, reception circuits 32 and 33, a microcomputer 34 and a switching circuit 35. The transmission circuit 31 and the reception circuits 32 and 33 are connected to the microcomputer 34, respectively. A transmission / reception antenna 36 is connected to the transmission circuit 31 and the reception circuit 33 via a switching circuit 35. The switching circuit 35 is a circuit for selectively connecting the transmission / reception antenna 36 to the transmission circuit 31 or the reception circuit 33. The receiving circuit 32 is connected to a receiving antenna 32a.

  The transmission circuit 31 converts the request signal output from the microcomputer 34 into a radio wave of a predetermined frequency and outputs it via the transmission / reception antenna 36. The transmission circuit 31 converts the transponder drive signal output from the microcomputer 34 into a radio wave of a predetermined frequency, generates a transponder drive radio wave, and outputs it via the transmission / reception antenna 36. That is, both the request signal and the transponder driving radio wave are output from the transmission / reception antenna 36. That is, the output antenna for the request signal and the output antenna for the transponder driving radio wave are shared.

  The receiving circuit 32 can receive the ID code signal from the portable device 12 via the receiving antenna 32a. The reception circuit 32 demodulates the ID code signal into a pulse signal to generate a reception signal, and outputs the reception signal to the microcomputer 34. The receiving circuit 33 can receive a transponder signal from the portable device 12 via the transmission / reception antenna 36. At this time, the transmitting / receiving antenna 36 is connected to the receiving circuit 33 by the switching circuit 35. The reception circuit 33 demodulates the transponder signal into a pulse signal to generate a reception signal, and outputs the reception signal to the microcomputer 34.

  The engine starter 17 is electrically connected to the microcomputer 34. The microcomputer 34 includes a CPU, a RAM, a ROM, etc. (not shown), and alternatively outputs a request signal and a transponder signal.

  Then, the microcomputer 34 compares the ID code set in advance with the ID code included in the received signal (ID code verification) when a received signal including the ID code is input. When the ID codes match, the microcomputer 34 outputs a start permission signal to the engine starter 17.

  In addition, when a reception signal including a transponder code is input, the microcomputer 34 compares a preset transponder code with a transponder code included in the reception signal (transponder code verification). When the transponder codes coincide with each other, the microcomputer 34 outputs a start permission signal to the engine starter 17. The engine is started by turning an operation knob (not shown) while this signal is output.

  As shown in FIG. 1, the portable device 12 includes a reception circuit 20, a microcomputer (microcomputer) 21, a transmission circuit 23, and a transponder 22. The receiving circuit 20 receives a request signal from the transmission / reception device 13 via a chip triaxial antenna 70 as a chip multi-axis antenna, and inputs the signal to the microcomputer 21. The microcomputer 21 outputs an ID code signal including a predetermined ID code set in advance when a request signal is input from the receiving circuit 20. The transmission circuit 23 modulates the ID code signal into a radio wave having a predetermined frequency and transmits it to the transmission / reception apparatus 13 via the chip triaxial antenna 70.

  The transponder 22 includes a transponder control unit 24. When receiving sufficient energy by electromagnetic waves, the transponder control unit 24 outputs a transponder signal including a preset ID code (transponder code) for a predetermined transponder. Specifically, the transponder control unit 24 outputs a transponder signal when receiving a transponder driving radio wave from the transmission / reception device 13.

Next, the structure of the portable device 12 will be described.
As shown in FIG. 2, the portable device 12 is formed in a substantially rectangular parallelepiped shape by a case 28 made of synthetic resin. The case 28 is partitioned into a battery storage portion 28b, a mechanical key storage portion 28c, and a circuit arrangement portion 28a. The battery 26 is accommodated in the battery accommodating portion 28b, and the mechanical key 27 is accommodated in the mechanical key accommodating portion 28c. A reception circuit 20, a microcomputer 21, a transmission circuit 23, a transponder 22, and a chip triaxial antenna 70 are mounted on a circuit board 29 provided in the circuit arrangement unit 28a.

  As shown in FIGS. 3 to 5, the chip triaxial antenna 70 includes a synthetic resin casing 81, and a transparent film 84 made of an insulator is attached to an opening thereof. The film 84 and the casing 81 are formed in a substantially cross shape. The casing 81 includes a substantially cross-shaped main body portion 82a having an accommodation recess 85, and a cap 82b that closes openings formed at four ends of the main body portion 82a. The main body 82a is provided with a housing recess 85 having a substantially cross shape.

  Two metal contacts 83 are provided on both sides of each cap 82b. That is, the contacts 83 are provided at eight locations in the chip triaxial antenna 70. As shown in FIG. 7, each contact 83 is insert-molded in the cap 82b. The contact 83 includes a mounting portion 83a having a substantially L-shaped cross section protruding from the cap 82b toward the circuit board 29, a connection portion 83b connected to the end of the mounting portion 83a, and protruding from both side surfaces of the cap 82b. have. The chip triaxial antenna 70 is fixed by soldering these mounting portions 83a to the circuit board 29.

  As shown in FIGS. 3 to 5, a core 71 made of a magnetic material is accommodated in the casing 81. As shown in FIG. 7, the core 71 is disposed so as not to interfere with each contact 83. The core 71 is configured by extending and forming a plurality of (four in the present embodiment) arm portions 72a in a different direction. That is, the core 71 is formed in a substantially cross shape by overlapping two core pieces 72 having a band shape in the center portion of each other. Therefore, both core pieces 72 are orthogonal to each other, and each arm portion 72 a extends outward from the orthogonal portion of both core pieces 72.

  As shown in FIGS. 4 to 6, a recess 72 b is formed in the orthogonal portion of both core pieces 72 by curving the core piece 72 in the thickness direction. When the two core pieces 72 are overlapped with each other, the inner side surface 72 c of the recess 72 b comes into contact with the other core piece 72.

  Moreover, both the core pieces 72 are comprised by laminating | stacking a plurality of core sheets (in this embodiment, 30 sheets). In this embodiment, the plate thickness of each core sheet is set to 15 to 20 · high. Each core sheet is made of a flexible material. In the present embodiment, each core sheet is amorphous (amorphous) and is formed of an alloy made of Co and Ni.

  Further, a winding portion 73 is formed on each arm portion 72a and the casing 81. The winding portion 73 includes an X-axis winding portion 73a, a Y-axis winding portion 73b, and a Z-axis winding portion 73c. The X-axis winding portion 73a and the Y-axis winding portion 73b are configured by winding an electric wire 74 around the arm portion 72a. The direction of the magnetic flux generated in the X-axis winding portion 73a and the direction of the magnetic flux generated in the Y-axis winding portion 73b are orthogonal to each other. Further, each X-axis winding portion 73 a and each Y-axis winding portion 73 b are located on substantially the same plane in the thickness direction of the casing 81. The outer surfaces of each X-axis winding portion 73a and each Y-axis winding portion 73b are substantially flat to improve the installation of the core 71. Each X-axis winding portion 73 a and each Y-axis winding portion 73 b are connected by an electric wire 74 at an orthogonal portion of both core pieces 72.

  Further, the Z-axis winding portion 73c is hooked on the winding recessed portion 86 provided on the front end surface of each cap 82b, and wraps the electric wire 74 along the shortest distance line passing through the cap 82b of the casing 81. Is made up of. The inner back surface of each wound recess 86 has a substantially arc shape when viewed from the direction shown in FIG. Therefore, it is possible to prevent the electric wire 74 from being cut when the electric wire 74 is strongly wound to configure the Z-axis winding portion 73c. The direction of the magnetic flux generated in the Z-axis winding portion 73c is orthogonal to the direction of the magnetic flux generated in the X-axis winding portion 73a and the Y-axis winding portion 73b. The ends of the electric wires 74 extending from the X-axis winding portion 73a, the Y-axis winding portion 73b, and the Z-axis winding portion 73c are connected to the connection portion 83b of the contact 83, respectively. The contact 83 may be connected to the wire 74 or may not be connected. The contact 83 is not connected to the chip triaxial antenna 70 only.

According to this embodiment, the following effects can be obtained.
(1) The chip triaxial antenna 70 extends the four arm portions 72a in different directions to form the X-axis winding portion 73a and the Y-axis winding portion 73b on the arm portion 72a, and each core piece 72. It is comprised by forming the Z-axis winding part 73c along the line which passes along the front-end | tip. Therefore, the chip triaxial antenna 70 has the same function as the three uniaxial antennas 102 (shown in FIG. 22) arranged in different directions (directions orthogonal to each other). As a result, the mounting space for the chip triaxial antenna 70 can be reduced more than the mounting space for three uniaxial antennas 102. That is, the chip triaxial antenna 70 can be downsized, and the chip triaxial antenna 70 can be easily mounted on the portable device 12.

  Further, unlike the chip triaxial antenna 91 shown in FIG. 8, the X axis winding portion 73 a and the Y axis winding portion 73 b do not overlap each other, so that the chip triaxial antenna 70 is thinner than the chip triaxial antenna 91. Can be

  Furthermore, as in the case where the Z-axis winding portion 73c is arranged on the side opposite to the circuit board 29 side of the core 71 (chip triaxial antenna 70 in the second embodiment to be described later), the Z-axis winding portion 73c has X Since the axial winding portion 73a and the Z-axis winding portion 73c do not overlap, the chip triaxial antenna 70 can be thinned.

  (2) Since the core 71 is formed in a substantially cross shape, an empty space A1 is generated at a location surrounded by the adjacent arm portion 72a and the Z-axis winding portion 73c (shown in FIG. 3). Therefore, the empty space A1 can be effectively used for other purposes, for example. Specifically, electrical components such as resistors that are not easily affected by electromagnetic waves can be arranged in the empty space A1.

  Here, the structure shown in FIG. 8 is considered as a chip triaxial antenna. That is, the chip triaxial antenna 91 has a rectangular core 71, and an X-axis winding portion 73a, a Y-axis winding portion 73b, and a Z-axis winding portion 73c are formed on the core 71. In this case, the Z-axis winding portion 73 c is configured by rotating the electric wire 74 along the side surface 92 of the core 71. Therefore, the electric wire 74 cannot be circulated along the virtual line A3 corresponding to the outline of the chip triaxial antenna 70 of the present embodiment, and the chip triaxial antenna 91 is increased in size. It is also conceivable to form the core 71 in the same size as the chip triaxial antenna 70, but when forming the X-axis winding portion 73a and the Y-axis winding portion 73b, the electric wire 74 can be successfully applied to the winding surface 93. There is a possibility that it cannot be wound. Therefore, the projected area of the chip triaxial antenna 70 in this embodiment is smaller than that of the chip triaxial antenna 91 of FIG. 8 when viewed from the thickness direction. In other words, the chip triaxial antenna 70 is smaller in size than the chip triaxial antenna 91 in the area A2 surrounded by the virtual line A3 and the Z-axis winding portion 73c when viewed from the thickness direction of the core 71. Can be That is, the mounting area of the chip triaxial antenna 70 necessary for the circuit board 29 can be reduced.

  Further, since the core 71 is formed in a substantially cross shape, the center of gravity of the chip triaxial antenna 91 is located at an orthogonal portion of both core pieces 72 which is the central portion. Therefore, when mounting the chip triaxial antenna 91, the chip triaxial antenna 91 can be stably sucked by the suction chuck.

Further, compared to the case where the core 71 is formed in a substantially T shape, the magnetic flux distribution generated when the Z-axis winding portion 73c is energized becomes uniform. Therefore, the sensitivity of the chip triaxial antenna 91 is improved.
(3) Since the recessed part 72b is formed in the orthogonal part of each core piece 72 and the inner surface 72c of the recessed part 72b is in contact with the other core piece 72, the core 71 can be made still thinner. In addition, since one core piece 72 is engaged in the recess 72b formed in the other core piece 72, the core pieces 72 can be positioned orthogonal to each other when the core 71 is manufactured. Moreover, since the core piece 72 has flexibility, it does not break when an impact is applied. Therefore, it is possible to prevent the impact resistance of the core 71 from being lowered when the core 71 is thinned.

  (4) Each core piece 72 is made of a magnetic material, and is configured by laminating a plurality of flexible core sheets. Therefore, even when only one core sheet breaks when an impact is applied to the chip triaxial antenna 70, the other core sheet is not broken, so the entire core piece 72 is not broken. . Therefore, the impact resistance of the chip triaxial antenna 70 is further improved.

  (5) Contact points 83 each having a mounting portion 83a soldered to the circuit board 29 are provided on both sides of each cap 82b. There are at least four contacts 83 provided on the chip triaxial antenna 70, and six contacts 83 are required in view of the ease of soldering the electric wires 74. However, the chip triaxial antenna 70 of the present embodiment is provided with eight contacts 83 including those in which the end of the electric wire 74 is not connected to the connection portion 83b. Therefore, the chip triaxial antenna 70 can be more reliably fixed. In addition, since each contact 83 is provided on the cap 82 b, the chip triaxial antenna 70 can be fixed more reliably than when each contact 83 is disposed in the vicinity of the orthogonal portion of both core pieces 72.

  (6) Since the core 71 is accommodated in the casing 81, the core 71 can be easily positioned in the thickness direction of the chip triaxial antenna 70. Moreover, since the to-be-wrapped recessed part 86 can be provided in the casing 81, formation of the Z-axis winding part 73c becomes easy.

(Second Embodiment)
A second embodiment embodying the present invention will be described below with reference to FIGS. In the second embodiment, detailed description of the same parts as those in the first embodiment is omitted.

  As shown in FIGS. 9 and 10, the casing 81 accommodates a core 71 on which an X-axis winding portion 73a and a Y-axis winding portion 73b are formed and a Z-axis winding portion 73c. The opening 81 is covered with a cover 81a. The Z-axis winding portion 73 c is disposed on the opposite side of the circuit board 29 on which the chip triaxial antenna 70 is mounted in the thickness direction of the core 71. The Z-axis winding portion 73c has a rectangular annular shape. The Z-axis winding portion 73 c is formed by rotating the electric wire 74 along the shortest distance line passing through the tip of each core piece 72. Each corner of the Z-axis winding portion 73 c coincides with the leading edge of each core piece 72 in the thickness direction of the chip triaxial antenna 70. The outer peripheral edge of the Z-axis winding portion 73 c does not protrude from the leading edge of each core piece 72.

Therefore, according to the present embodiment, the following effects can be obtained.
(7) In the thickness direction of the core 71, the Z-axis winding portion 73c is disposed on the side opposite to the circuit board 29 side on which the chip triaxial antenna 70 is mounted. Therefore, the Z-axis winding portion 73c is formed in comparison with the chip triaxial antenna 70 of the first embodiment in which the Z-axis winding portion 73c is formed by rotating the electric wire 74 along the tip surface of each core piece 72. The possible range becomes wider. Therefore, the sensitivity of the chip triaxial antenna 70 in the Z-axis direction can be improved.

  Further, in comparison with the first embodiment, each core piece 72 can be extended only by the thickness of the Z-axis winding portion 73c in the longitudinal direction. Nevertheless, the sensitivity of the chip triaxial antenna 70 in the X-axis direction and the Y-axis direction can be greatly improved.

  Therefore, the sensitivity of the chip triaxial antenna 70 can be improved without increasing the mounting area of the chip triaxial antenna 70 necessary for the circuit board 29. That is, even when the mounting area of the chip triaxial antenna 70 is determined in advance, the sensitivity of the chip triaxial antenna 70 can be improved.

  (8) The electric wires 74 forming the Z-axis winding portion 73 c are arranged so as not to protrude from the tip of each core piece 72. Here, if each core piece 72 is not extended in the longitudinal direction, the chip triaxial antenna 70 can be downsized in the longitudinal direction of each core piece 72 without lowering the sensitivity of the chip triaxial antenna 70. Therefore, the mounting area of the chip triaxial antenna 70 necessary for the circuit board 29 can be further reduced, which is advantageous for downsizing the portable device 12.

(Third embodiment)
A third embodiment embodying the present invention will be described below with reference to FIGS. In the third embodiment, detailed description of the same parts as those in the first embodiment is omitted.

  As shown in FIGS. 11 to 13, the casing 81 is covered with a box-shaped cover 81 a having a lower opening. Four claw portions 94 project from the surface of the casing 81 on the circuit board 29 side. Each claw portion 94 is disposed in a state where the outer side surface thereof coincides with the outer peripheral edge of the casing 81, and an engaging claw 94 a is projected from the inner side surface of each claw portion 94. Each engagement claw 94 a is engaged with each claw portion 94 penetrating the circuit board 29.

  The casing 81 is provided with a housing recess 85 having a substantially cross shape. In addition, the casing 81 is provided with an accommodation recess 95 that is disposed at a location surrounded by the accommodation recess 85 and the outer periphery of the casing 81 and has a substantially triangular shape.

  In the housing recess 85, an X-axis winding portion 73 a formed by winding the electric wire 74 around one core piece 72 and a Y-axis winding portion formed by winding the electric wire 74 around the other core piece 72. 73b is housed. The electric wires 74 forming the X-axis winding portion 73a and the Y-axis winding portion 73b are wound almost entirely on the respective core pieces 72. The X-axis winding portion 73a and the Y-axis winding portion 73b are formed in advance on the core pieces 72 before the core pieces 72 are overlapped so as to be substantially cross-shaped at the center of each other. . That is, with the X-axis winding portion 73a and the Y-axis winding portion 73b formed in advance by winding the electric wire 74 around each core piece 72, the X-axis winding portion 73a and the Y-axis winding portion 73b are connected to both cores. The pieces 72 are accommodated in the accommodating recess 85 by being overlapped so as to be substantially cross-shaped at the center portions of each other.

  Each accommodation recess 95 is provided with one contact 83. That is, the contacts 83 are provided at four locations in the chip triaxial antenna 70. Three of the contacts 83 are arranged so as to be equally spaced from the X-axis winding portion 73a and the Y-axis winding portion 73b, respectively, and the remaining one is arranged so as to be offset from the X-axis winding portion 73a side. Has been. Therefore, each contact 83 is disposed so as not to be symmetrical with respect to the X-axis winding portion 73a and the Y-axis winding portion 73b when the chip triaxial antenna 70 is viewed from the thickness direction.

  As shown in FIG. 13, each contact 83 is press-fitted into a through hole 81 b provided in the casing 81. The contact 83 has a circular cross section, and includes a mounting portion 83a protruding from the casing 81 toward the circuit board 29, a connection portion 83b connected to the end of the mounting portion 83a, and protruding into the housing recess 95. have. The chip triaxial antenna 70 is fixed by soldering the mounting portion 83a through the circuit board 29.

Therefore, according to the present embodiment, the following effects can be obtained.
(9) Since the chip triaxial antenna 70 is manufactured by superimposing the two core pieces 72 around which the electric wires 74 are wound, when the chip triaxial antenna 70 is manufactured, the electric wires 74 are formed on the overlapping portions of the core pieces 72. Can be wound. Therefore, compared with the case where the chip triaxial antenna 70 is manufactured by winding the electric wire 74 after the two core pieces 72 are overlapped, the range in which the X axis winding portion 73a and the Y axis winding portion 73b can be formed is In the piece 72, only the overlapping part is extended. Therefore, the sensitivity of the chip triaxial antenna 70 in the X-axis direction and the Y-axis direction can be improved. Therefore, the sensitivity of the chip triaxial antenna 70 can be improved without increasing the mounting area of the chip triaxial antenna 70 necessary for the circuit board 29.

  In the first and second embodiments, since the electric wire 74 is wound around each arm portion 72a to form the X-axis winding portion 73a and the Y-axis winding portion 73b, it is necessary to wrap the electric wire 74 in four times. There is. On the other hand, in this embodiment, since the electric wire 74 is wound around almost the entire core piece 72 to form the X-axis winding portion 73a and the Y-axis winding portion 73b, only the electric wire 74 is wound twice. It's okay. Therefore, workability at the time of manufacturing the chip triaxial antenna 70 can be improved.

  In addition, when the X-axis winding portion 73a and the Y-axis winding portion 73b are formed, the conventional equipment that has been used to manufacture the uniaxial antenna 102 can be used. The manufacturing cost can be reduced.

  (10) The mounting portion 83 a of the contact 83 is soldered in a state of penetrating the circuit board 29. Therefore, the chip triaxial antenna 70 is not fixed only by the adhesive force of the solder as in the first and second embodiments, but is also fixed by the frictional force between the outer peripheral surface of the mounting portion 83a and the circuit board 29. Is done. In addition, a solder fillet is formed at a connection portion between the mounting portion 83a and the circuit board 29. Therefore, the fixing strength of the chip triaxial antenna 70 can be improved.

  (11) Each contact 83 is disposed so as not to be symmetrical with respect to the X-axis winding portion 73a and the Y-axis winding portion 73b when each core piece 72 is viewed from the thickness direction. Therefore, even if the chip triaxial antenna 70 is attached to the circuit board 29 in the wrong direction, each contact 83 cannot be penetrated through the circuit board 29. Therefore, it is possible to prevent the portable device 12 from malfunctioning due to erroneous attachment of the chip triaxial antenna 70.

  (12) On the side of the circuit board 29 in the thickness direction of each core piece 72, a claw portion 94 that is engaged in a state penetrating the circuit board 29 is disposed. Therefore, when the circuit board 29 is turned over in order to solder the chip triaxial antenna 70, the chip triaxial antenna 70 is temporarily fixed to the circuit board 29 by the claw portion 94, so that it does not fall off. . Therefore, the mounting work of the chip triaxial antenna 70 is facilitated.

  The chip triaxial antenna 70 is fixed to the circuit board 29 not only by soldering each contact 83 but also by engaging each claw portion 94. Therefore, the fixing strength of the chip triaxial antenna 70 is further improved.

In addition, you may change each said embodiment as follows.
-In the said 1st Embodiment, as shown in FIGS. 14-16, you may form each core piece 72 by sintering.

  In each of the above embodiments, as shown in FIG. 17, the core piece 72 may be integrally formed to constitute the core 71. When the core 71 is made of an amorphous alloy, the core 71 is formed by stacking a plurality of core sheets having a substantially cross shape. Moreover, when the core 71 is formed of ferrite, the core 71 is formed by press molding. If comprised in this way, since the direction of each arm part 72a is preset, each arm part 72a can be positioned reliably. Therefore, the chip triaxial antenna 70 can be reliably mounted. In addition, the chip triaxial antenna 70 can be prevented from becoming thick.

In each of the above embodiments, the core 71 may be formed in a substantially T shape by overlapping the two core pieces 72. The core 71 may be integrally formed in a substantially T shape.
In each of the above embodiments, only one of the orthogonal portions of each core piece 72 may be curved in the thickness direction of the core piece 72 to form the recess 72b.

  In the first embodiment, each contact 83 is provided on both sides of the cap 82b. However, as shown in FIG. 18, each contact 83 may be provided at the tip edge of the cap 82b. In this case, the contacts 83 of the chip triaxial antenna 70 are provided at a total of four locations.

  As shown in FIGS. 19 and 20, each contact 83 may be provided at a location surrounded by the adjacent arm portion 72a and the Z-axis winding portion 73c (location corresponding to the vacant space A1 in the embodiment). . If comprised in this way, compared with the case where each contact 83 is provided in the front-end edge of the cap 82b (illustrated in FIG. 18), the chip triaxial antenna 70 is reduced in size. Even if the mounting portion 83a is set to be longer than that in the above embodiment, the mounting portion 83a does not interfere with the winding portion 73. Therefore, since the contact area between the chip triaxial antenna 70 and the circuit board 29 can be increased, the chip triaxial antenna 70 can be easily mounted.

  In the second embodiment, the Z-axis winding portion 73c may be disposed on the circuit board 29 side of the core 71. Further, the Z-axis winding part 73c may be arranged on the circuit board 29 side of the core 71 and the opposite side thereof. If comprised in this way, since the Z-axis coil | winding part 73c can be increased twice, the sensitivity in the Z-axis direction of the chip | tip triaxial antenna 70 can be improved.

  In the second embodiment, the electric wires 74 that form the Z-axis winding portion 73 c may not circulate along the shortest distance line passing through the tip of each core piece 72. That is, for example, as shown in FIG. 21, each corner of the Z-axis winding portion 73 c may not coincide with the leading edge of each core piece 72 in the thickness direction of the chip triaxial antenna 70.

In each of the above embodiments, the core piece 72 may be mounted on the circuit board 29 as it is without being housed in the casing 81.
Next, the technical idea grasped by the above embodiment and other embodiments will be described below.

  (1) Each core piece is configured by laminating a plurality of flexible core sheets. Therefore, according to the technical idea (1), the impact resistance of the chip multi-axis antenna is further improved.

  (2) A plurality of contacts provided with a connection portion connected to the electric wire and a mounting portion mounted in a state of penetrating the circuit board are provided. Therefore, according to the technical idea (2), the fixing strength of the chip triaxial antenna can be improved.

  (3) In the technical idea (2), the contact points are not symmetrical with respect to the X-axis winding portion and the Y-axis winding portion when the core pieces are viewed from the thickness direction. The chip triaxial antenna is characterized by being arranged as follows. Therefore, according to the technical idea (3), erroneous attachment of the chip triaxial antenna can be prevented.

  (4) A claw portion to be engaged in a state penetrating through the circuit board is disposed on the circuit board side in the thickness direction of each core piece. Therefore, according to the technical idea (4), the mounting operation of the chip triaxial antenna is facilitated.

The block diagram which shows the electric constitution of the remote control device for vehicles in 1st Embodiment. Sectional drawing of a portable machine. The front view of a chip | tip triaxial antenna. AA line sectional view of Drawing 3. The whole perspective view of a chip triaxial antenna. The whole perspective view which shows a core. BB sectional drawing of FIG. The whole perspective view of a chip triaxial antenna which compares and shows composition different from a 1st embodiment. The back view of the chip | tip triaxial antenna in 2nd Embodiment. The DD sectional view taken on the line of FIG. The front view of the chip | tip triaxial antenna in 3rd Embodiment. The EE sectional view taken on the line of FIG. FF sectional view taken on the line of FIG. Sectional drawing of the chip | tip triaxial antenna in other embodiment. The whole perspective view of the chip triaxial antenna in other embodiments. The whole perspective view showing the core in other embodiments. The whole perspective view showing the core in other embodiments. Sectional drawing of the chip | tip triaxial antenna in other embodiment. The front view of the chip | tip triaxial antenna in other embodiment. The CC sectional view taken on the line of FIG. The back view of the chip | tip triaxial antenna in other embodiment. Sectional drawing of the portable device in a prior art.

Explanation of symbols

  70... Chip triaxial antenna as chip multi-axis antenna, 71... Core, 72... Core piece, 72 a... Arm part, 72 b .. Recess, 72 c. 73b ... Y-axis winding part, 73c ... Z-axis winding part, 74 ... electric wire, 81 ... casing, 85 ... receiving recess (recess), 86 ... wound recess.

Claims (3)

An X-Y axis antenna is formed by winding an electric wire around a substantially cross-shaped core made of a magnetic material to form an X-axis winding portion and a Y-axis winding portion, or an electric wire is attached to each of two core pieces made of a magnetic material. To form an X-axis winding portion and a Y-axis winding portion, and by arranging these two core pieces in a substantially cross shape, an X-Y axis antenna is obtained.
The XY axis antenna is accommodated in a substantially cross-shaped recess corresponding to the outer shape of the XY axis antenna provided on a diagonal line of a casing integrally formed of a synthetic tree material in a rectangular shape. Chip multi-axis antenna. The chip multi-axis antenna according to claim 1,
A chip multi-axis antenna formed as a Z-axis antenna by continuously forming a wound recess on the outer peripheral surface of the casing and winding a wire around the wound recess to form a Z-axis winding portion. The chip multi-axis antenna according to claim 1 or 2,
By winding an electric wire around two core pieces made of a magnetic material to form an X-axis winding portion and a Y-axis winding portion, and by superimposing these two core pieces in a cross shape at the center of each other Adopting the configuration of XY axis antenna
The concave portion is formed with a first concave portion corresponding to the outer shape of one core piece on which the X-axis winding portion or the Y-axis winding portion is formed, and the Y-axis winding portion or the X-axis winding portion. A second recess corresponding to the outer shape of the other core piece;
The first recess is formed to a depth corresponding to the thickness of the central portion of the two core pieces superimposed in a substantially cross shape, and the second recess has an opening on the opening side of the first recess. A chip multi-axis antenna in which a recess is formed to a depth corresponding to the thickness of the other core piece.

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