JPWO2012067245A1 - Mobile body equipped with an antenna device - Google Patents

Abstract

An automobile (60) equipped with an antenna device (10) according to an embodiment of the present invention has an antenna device (10) attached to one A pillar (1a) extending from a body (62) to a roof (61). The height of the mounting position of the antenna device (10) is 2/3 or less of the height of the upper end of the A pillar (1a) relative to the lower end of the A pillar (1a).

Description

  The present invention relates to a mobile object equipped with an antenna device.

  In the field of in-vehicle antennas (antenna devices mounted on automobiles), various antenna devices used in various bands have been developed due to the recent development of communication networks.

  As an example, the car navigation system includes GPS (Global Positioning System), VICS (Vehicle Information and Communication System; registered trademark) and ETC (Electronic Toll Collection; non-stop automatic fee payment). An antenna device capable of transmitting and receiving microwaves of 1 GHz to 10 GHz used in ITS (Intelligent Transport Systems) such as a system) is used.

  Further, it is common that a car navigation system is equipped with a tuner that receives not only the ITS but also radio broadcasts and terrestrial digital broadcasts. Accordingly, the operating band required for the antenna device for the car navigation system includes an AM frequency of 526.5 kHz to 1606.5 kHz, a VHF frequency of 60 MHz band or 87.5 MHz to 108 MHz, and 470 MHz to be used for terrestrial digital broadcasting. The UHF frequency of 770 MHz is also included and covers a wide range.

  The in-vehicle antenna has a problem that the reception sensitivity is lowered depending on the direction of the vehicle body. More specifically, when the antenna device enters a “shadow” of a metal member constituting the vehicle body (an area where electromagnetic waves incident from a specific direction do not reach), there is a problem that the reception sensitivity is remarkably lowered. . In order to solve such a problem, various receivers that perform diversity reception have been widely used. Diversity reception is a technique for improving reception sensitivity by selecting or combining high-frequency signals supplied from a plurality of antenna devices attached at different positions.

  In Patent Document 1, in a receiving system for an on-vehicle digital terrestrial television, an antenna device having superior reception sensitivity is selected from among a plurality of antenna devices, and only the selected antenna device is connected to a receiving circuit. Describes a technique for reducing the number of antennas to be smaller than the number of antenna devices.

  As shown in FIG. 33, the receiving system of Patent Document 1 includes four planar antenna devices 120 </ b> A to 120 </ b> D provided at two places on the left and right of the windshield of the automobile 110 and two places on the left and right of the rear glass, and a rear trunk room. And a selector circuit 121 installed therein. Each of the antenna devices 120A to 120D is connected to the selector circuit 121 via the cords 112A to 112D.

  The selector circuit 121 supplies the terrestrial digital television receiver 122 with a high-frequency signal input from two antenna devices having superior reception sensitivity among the four antenna devices 120A to 120D. The terrestrial digital television receiver 122 includes two receiving circuits to which two high-frequency signals supplied from the selector circuit 121 are input, and a video signal and an audio signal are obtained by combining the output signals of the two receiving circuits. Is demodulated. Note that which antenna device the selector circuit 121 supplies to the high-frequency signal input to the terrestrial digital television receiver 122 is determined based on position information indicating the current position of the automobile 110 acquired using the GPS 126. .

Japanese Patent Publication “JP 2007-281611 A” (released on October 25, 2007)

  However, when diversity reception is performed in a moving body such as an automobile, it is necessary to install a plurality of antenna devices on the moving body. For this reason, even if the number of receiving circuits is reduced as in the configuration of Patent Document 1, the cost, the number of installation steps, and the like cannot be sufficiently reduced. In addition, when the number of antenna devices installed on the moving body increases, there may be a problem that the aesthetic appearance is deteriorated and the freedom of design is impaired.

  The present invention has been made in view of the above problems, and its object is to improve the reception sensitivity without performing diversity reception by devising both the structure of the antenna device and the arrangement of the antenna device. An object of the present invention is to realize a movable body equipped with an antenna device.

  In order to solve the above problems, a mobile body according to the present invention is a mobile body on which an antenna device is mounted, and a plurality of windows are provided on a side surface so as to be interposed between two windows adjacent to each other. In the moving body provided with an intervening portion extending from the roof portion of the moving body, the antenna device is a radiating element disposed in a two-dimensional plane, and includes a first end of the radiating element. A first root portion provided with a feeding point; a second root portion including the other end of the radiating element and provided with a second feeding point; the first root portion and the second root portion. The antenna device is attached to the interposition part, and the height of the mounting position of the antenna device with respect to the lower end of the interposition part is The upper end of the interposition part relative to the lower end of the interposition part Is 2/3 or less of the height, it is characterized in that.

  The two-dimensional surface is not limited to a flat surface, and may be a surface having a three-dimensional shape obtained by cutting a part of a curved surface such as a cylindrical surface, a spherical surface, a paraboloid, or a hyperboloid.

  Further, the roof portion refers to a portion of the outer shell of the moving body that is above the plurality of windows.

  The present invention has the effect of providing a moving body equipped with an antenna device having good reception sensitivity.

1 is an external view of an automobile equipped with an antenna device according to an embodiment of the present invention. It is a figure which shows the example of an external appearance structure of the front side of the compartment of the motor vehicle shown in FIG. It is a figure which shows the structure of the antenna apparatus mounted in the motor vehicle shown in FIG. It is an enlarged view of the antenna device arrangement | positioning area | region of the front side of the compartment of the motor vehicle shown in FIG. It is an enlarged view of another example of the antenna device arrangement area on the front side of the passenger compartment of the automobile shown in FIG. It is a top view which shows the structure of the radiation element provided in the antenna apparatus shown in FIG. It is a schematic diagram which shows the state which has arrange | positioned the short circuit member in the radiation element which has a meander shape, and produced the some electroconductive path | route in the radiation element. It is a schematic diagram explaining the measurement condition of the experiment for showing the effect of an antenna device. It is a top view which shows schematic structure of another example of the antenna shown in FIG. 10 is a graph showing the VSWR characteristics of the antenna devices of FIGS. 6 and 9. It is a graph which shows the VSWR characteristic of the antenna apparatus of FIG. 6 when changing the thickness of a dielectric material. It is a graph which shows the radiation pattern of the antenna apparatus of FIG. 6, (a) in a figure is a radiation pattern in xy plane, (b) in the figure is radiation pattern in yz plane, (c) in a figure is The radiation patterns on the zx plane are respectively shown. It is a top view which shows schematic structure of another example of the antenna apparatus of FIG. It is a top view which shows schematic structure of another example of the antenna apparatus of FIG. It is a top view which shows schematic structure of another example of the antenna apparatus of FIG. 16 is a graph showing VSWR characteristics of the antenna devices of FIGS. 13, 14, and 15. It is a graph which shows the VSWR characteristic of the antenna apparatus provided with the antenna of FIG. 13 when changing the thickness of a dielectric material. It is a graph which shows the radiation pattern of the antenna apparatus of FIG. 13, (a) in a figure is a radiation pattern in xy plane, (b) in a figure is a radiation pattern in yz plane, (c) in a figure is The radiation patterns on the zx plane are respectively shown. It is a top view which shows schematic structure of another example of the antenna apparatus shown in FIG. It is arrow sectional drawing at the time of cut | disconnecting A pillar 1a shown in FIG. 2 by the cutting line HH '. It is arrow sectional drawing at the time of cut | disconnecting A pillar 1a shown in FIG. 2 by the cutting line HH '. It is a figure which shows the modification of the example of arrangement | positioning shown in FIG. It is an enlarged view of another example of the antenna device arrangement | positioning area | region of the front side of the compartment of the motor vehicle which shows the other example of arrangement | positioning of an antenna device. It is a perspective view which shows the antenna apparatus mounted in the example 3 of arrangement | positioning of this embodiment. It is arrow sectional drawing which showed the state which cut | disconnected the antenna integrated type wire harness shown in FIG. 24 in cutting | disconnection line SS '. FIG. 26 is a cross-sectional view showing another example of the antenna-integrated wire harness shown in FIG. 25. It is the figure which evaluated the receiving characteristic of the antenna apparatus mounted in the motor vehicle shown in FIG. It is the figure which evaluated the receiving characteristic of the antenna apparatus mounted in the motor vehicle shown in FIG. It is the figure which evaluated the receiving characteristic of the antenna apparatus mounted in the motor vehicle shown in FIG. It is the elements on larger scale of the compartment which showed the other example of the arrangement | positioning position of the antenna apparatus mounted in the motor vehicle shown in FIG. It is the elements on larger scale of the compartment which showed the other example of the arrangement | positioning position of the antenna apparatus mounted in the motor vehicle shown in FIG. It is the elements on larger scale of the compartment which showed the other example of the arrangement | positioning position of the antenna apparatus mounted in the motor vehicle shown in FIG. It is a figure which shows a conventional structure.

  An embodiment of a mobile object equipped with an antenna device according to the present invention will be described. In the following description, a typical automobile (ordinary car) as a moving body will be described. However, the present invention is not limited to this, and any moving body having a plurality of windows on the side surface may be used. The present invention can be applied to any moving body. That is, the moving body referred to here includes not only automobiles but also airplanes and ships. The antenna device may be used for transmission / reception, transmission-only, or reception-only.

  In the following, an embodiment of the moving body of the present invention and a detailed structure of the radiating element of the antenna device mounted thereon will be described, and finally, some aspects of the arrangement position of the radiating element of the antenna device will be exemplified. In addition, the antenna characteristics in these modes will be described.

Embodiment 1
A mode in which an antenna device is arranged inside a pillar will be described as a first embodiment. First, common items will be described, and then several aspects of the arrangement positions of the radiating elements of the antenna device will be described.

<Common items>
FIG. 1 is a diagram illustrating an appearance of an automobile 60 that is a typical example of a moving object.

  A plurality of windows 630 to 632 are provided on the side surface of the automobile 60. Specifically, as shown in FIG. 1, a front window (so-called windshield) 630 that is a window disposed on the front side surface, a side window 631 that is a window disposed on the right side surface and the left side surface, and the rear side surface And a rear window 632 which is a window disposed in the window. These windows 630 to 632 are all located between the roof (roof portion) 61 and the body 62.

  In the present specification, the roof 61 is a generic name for various structures above the upper ends of the windows, and the body 62 is a generic name for various structures below the lower ends of the windows. It is. That is, the body 62 includes a passenger door 64, a trunk cover 66, a hood 67, and the like.

Pillar Between the two windows adjacent to each other among the plurality of windows 630 to 632, pillars 1a to 1c extending from the roof 61 to the body 62 are provided so as to be interposed between the two windows. Yes. The pillars 1 a to 1 c are for supporting the roof 61. In the automobile 60 of the present embodiment, as shown in FIG. 1, pillars 1 a to 1 c are provided at three locations (a total of six locations) on the front side, the side, and the rear on the driver seat side and the passenger seat side. Specifically, (1) the A-pillar 1a disposed between the front window 630 and the side window 631 provided on the driver's seat (or passenger seat) entrance / exit door 64, and (2) the driver's seat (or B-pillar 1b disposed at the boundary between the side windows 631 provided on the passenger door and the passenger door on the rear seat, and (3) the side provided on the passenger door on the rear seat. A C pillar 1 c provided between the window 631 and the rear window 632 is provided. The pillars 1 a to 1 c have upper ends that are boundary portions with the roof 61, and lower ends that are boundary portions with the body 62.

  FIG. 2 is a diagram illustrating an example of an external configuration on the front side of the interior of the automobile 60 illustrated in FIG. 1. FIG. 2 shows a front window 630, side windows 631 provided on the driver's and passenger's passenger doors 64, respectively, and an A pillar 1a provided therebetween. In the present embodiment, the antenna device 10 is disposed on the A pillar 1a.

  Each of the pillars 1a to 1c includes an interior material (insulating material) and an exterior material (conductor) facing each other, and has a hollow structure having a hollow portion along the extending direction thereof. Details will be described later.

Antenna Device The antenna device 10 includes a radiating element 11 and an insulator 12 disposed on the back surface of the radiating element 11 as schematically shown in FIG.

  The radiating element 11 is a flexible plate-like conductor, and is arranged in a two-dimensional plane. The “two-dimensional surface” here is not limited to a flat surface, but may have a three-dimensional shape obtained by cutting out a part of a curved surface such as a cylindrical surface, a spherical surface, a paraboloid, or a hyperboloid.

  The insulator 12 can be omitted. Whether or not the insulator 12 is provided depends on whether or not the surface of the object on which the antenna device 10 is installed is a conductor. If the surface of the object is a conductor, the insulator 12 needs to be provided. If the surface is not a conductor, the insulator 12 need not be provided. This point will be described later. However, if the surface is not a conductor, the provision of the insulator 12 does not cause a problem as an antenna function.

  In the present embodiment, the radiating element 11 (and the insulator 12 as necessary) is disposed inside the A pillar 1a.

  Here, FIG. 4 is a diagram showing the appearance of the A pillar 1a and its surroundings. FIG. 4 is a view of the A pillar 1a as seen from the inside of the automobile.

  The antenna device 10 is characterized by an attachment position in the A pillar 1a. That is, as shown in FIG. 4, the height of the mounting position of the antenna device 10 with respect to the lower end of the A pillar 1a is set to 2/3 or less of the height of the upper end of the A pillar 1a with respect to the lower end of the A pillar 1a. doing. In particular, in this embodiment, the height of the mounting position of the antenna device 10 with respect to the lower end of the A pillar 1a is set to 1/3 or more and 2/3 or less of the height of the upper end of the A pillar 1a with respect to the lower end of the A pillar 1a. The configuration is adopted.

  As will be described later, it is most preferable to employ a configuration in which the height of the mounting position of the antenna device 10 is not less than 1/3 and not more than 2/3 of the height of the upper end of the A pillar 1a. However, the present invention is not limited to this, and as shown in FIG. 5, a configuration is adopted in which the height of the mounting position of the antenna device 10 is 1/3 or less of the height of the upper end of the A pillar 1a. May be.

  In the present embodiment, one antenna device 10 is provided for one automobile 60. This is because the antenna device 10 used in the present invention is a good antenna device with high sensitivity and no directivity, and thus it is not necessary to provide a plurality of antenna devices as in the conventional configuration. However, the present invention does not exclude the installation of the second and subsequent antenna devices.

  In the present embodiment, a configuration in which the antenna device 10 is disposed in the A pillar 1a is described. However, the present invention is not limited to this, and can be provided in the B pillar 1b or the C pillar 1c. Even when the antenna device 10 is provided in the B pillar 1b or the C pillar 1c, the antenna device 10 is disposed so as to satisfy the above-described characteristic configuration.

-Details of Antenna Device Details of the antenna device 10 will be described below.

  FIG. 6 is a plan view showing the structure of the radiating element 11 of the antenna device 10.

  The radiating element 11 is formed on a base material such as a thin resin, and for example, a conductor wire, a conductor film, or a printed wiring can be used. It is good also considering the insulator 12 shown in FIG. 3 as a base material.

  The radiating element 11 is a single line having a conductive path continuous from one end to the other end. Since the radiating element 11 has a conductive path continuous from one end to the other end, the antenna device 10 functions as a loop antenna. The sensitivity (gain) of a loop antenna is generally higher than the gain of a dipole antenna or monopole antenna.

  As shown in FIG. 6, the radiating element 11 has a part with a predetermined length from one end (a part corresponding to the following winding part 211) and a part with a predetermined length from the other end (the following winding part). And the first portion 225 and 226 constitute the first and second root portions 225 and 226, respectively. And the remaining part except the 1st and 2nd fundamental part 225,226 from the radiation | emission element 11 is comprised as an intermediate part. That is, the intermediate part is a part that relays between the first root part 225 and the second root part 226.

  Part of the intermediate part is meandered. The remaining part of the intermediate portion constitutes the first wide portion 213 and the second wide portion 214.

  On the other hand, the first and second root portions 225 and 226 constitute the winding portion 211. The first wide portion 213 and the second wide portion 214 share a part of each other.

  To summarize the above configuration, the conductive path starts from the first root portion 225 from one end to the other end of the radiating element 11, and includes the first wide portion 213, the second wide portion 214, and the radiating portion 212. The second root part 226 continues in the order of the second root part 226, and the second root part 226 returns to a position adjacent to the first root part 225.

  In the first root portion 225, the direction of taking out from one end to the other end is leftward in FIG. 6 (the negative direction of the X axis), and in the second root portion 226, taking out from the other end to the one end is performed. The direction is the right direction in FIG. 6 (the positive direction of the X axis). That is, the two directions of taking out are opposite to each other.

  That is, in both of the two root portions 225 and 226, the extending directions thereof are opposite to each other so as to surround the feeding portion (feeding point) 222 (rotated 180 °).

  For this reason, it is possible to obtain a high radiation gain for each electromagnetic wave, regardless of whether the electromagnetic wave on the low frequency band side or the electromagnetic wave on the high frequency band side is transmitted / received.

  Furthermore, in the case of the first root portion 225, the extraction directions of the first and second root portions 225 and 226 of the radiating element 11 are the directions in which the feeder line 221 extends, that is, the leftward direction (X In the case of the second root portion 226, the feeding line 221 is opposite to the direction in which the feeding line 221 extends from the feeding unit 222 described later to the power source side.

  Specifically, in the winding part 211, in FIG. 6, the extending direction of the first root part 225 is upward (positive direction of the Z axis) and leftward (from the one end of the radiating element 11). X-axis negative direction, take-out direction). That is, the first root portion 225 includes a first straight portion 225o1 extending upward, and a first bent portion 225o2 (rear end straight portion) extending leftward from an end portion of the first straight portion 225o1.

  In addition, the extending direction of the second root portion 226 is downward (a negative direction of the Z axis) and rightward (a positive direction of the X axis, an extraction direction) from the other end of the radiating element 11. Yes. That is, the second root portion 226 includes a second straight portion 226o1 extending downward and a second bent portion 226o2 (rear end straight portion) extending rightward from an end portion of the second straight portion 226o1.

  As described above, in the winding part 211, the extending direction of each of the first and second root parts 225 and 226 is rotated by 90 ° so as to surround the power feeding part 222. .

  Further, a part of the intermediate portion of the radiating element 11 has a meander shape including a folded pattern at least once, more preferably two or more times in the radiating portion 212. The folding direction (Z-axis direction) of this meander-shaped folding pattern is the direction of taking out the second root portion 226 of the radiating element 11 in the winding portion 211 (positive direction of the X axis), that is, the second direction. It is perpendicular to the direction of the bent portion 226o2 (rear end straight portion).

  By the way, in the winding part 211, the above-described power feeding part 222 is formed in each of the two root parts 225 and 226. Each of the two root portions 225 and 226 is supplied with power from a power supply line 221 connected to the power supply portion 222. Specifically, the outer conductor of the coaxial cable constituting the feeder line 221 supplies power to the first root portion 225, and the inner conductor of the coaxial cable supplies power to the second root portion 226. In addition, a portion (a portion where the outer conductor is not exposed) that is adjacent to the portion where the outer conductor is exposed and is covered with an insulating outer skin is disposed on the first wide portion 213b.

  Regarding power supply from the power supply line 221, specifically, in the power supply unit 222, a signal of a predetermined frequency band is applied to the second root unit 226 via the inner conductor of the coaxial cable, and via the outer conductor, A ground potential is applied to the first root portion 225.

  Further, the line width (the length in the X-axis direction) of the first wide portion 213 that is located below the power supply line 221 and overlaps the power supply line 221 is set so that the winding portion 211 and the radiation portion 212 of the radiating element 11 are the same. It is wider than the line width of the constituent parts. For this reason, impedance matching between the power supply unit 222 and the power supply line 221 can be realized.

  Similarly to the first wide portion 213, the second wide portion 214 is also wider than the line width of the portion constituting the winding portion 211 and the radiation portion 212 of the radiating element 11.

  On the other hand, unlike FIG. 6, if the power supply line 221 extends from the power supply unit 222 in the negative direction of the Z axis, the second wide portion 214 serves as the first wide portion 213. become. That is, in this case, the line width (the length in the X-axis direction) of the second wide portion 214 that is located below the feeder line 221 and overlaps the feeder line 221 is equal to the winding portion 211 of the radiating element 11 and the radiation. It can be said that the line width of the portion constituting the portion 212 is wider.

  Further, as will be described later, the power supply line 221 connected to the power supply unit 222 of the radiating element 11 is bundled and arranged with a plurality of electric wires constituting the wire harness disposed inside the pillar in the vicinity of the power supply unit 222. Is done. Here, as an example of the size of the antenna device 10 (radiating element 11), the length in the left-right direction (X-axis direction) in FIG. 6 can be 125 mm, and the length in the vertical direction (Z-axis direction) can be 25 mm. An example of the thickness of the radiating element 11 can be 1 mm. And this antenna apparatus 10 can be attached to a wire harness so that the length of an up-down direction (Z-axis direction) may follow the circumferential direction of a wire harness.

  Further, the short-circuit member 231 is disposed in the meander shape of the radiating portion 212. The short-circuit member 231 is not limited to being provided as an independent member, and may be integrally formed with the radiating element, for example, using the same material as the radiating element that forms the conductive path. Here, the role of the short-circuit member 231 will be described below with reference to FIG.

● Role of Short-Circuit Member 231 FIG. 7 is a schematic diagram showing a state in which the short-circuit member 331 is arranged in the radiating element 315 having a meander shape and a plurality of conductive paths are generated in the radiating element 315.

  An antenna 301 illustrated in FIG. 7 includes a radiating element 315 that is one line, and the radiating element 315 has a meander shape. That is, the radiating element 315 is meandered. A feed line is connected to the radiating element 315 at the feed unit 322.

  The short-circuit member 331 short-circuits, for example, two or more different points of the meandering radiation element 315 (a plurality of points). In the example of FIG. 7, the two straight portions extending in the vertical direction located at both ends of the short-circuit member 331 are short-circuited. Accordingly, the radiation element 315 includes a first path (first conductive path) indicated by a solid line corresponding to the first wavelength λ1 and a second path indicated by a broken line corresponding to the second wavelength λ2. A path (second conductive path) is formed.

  7 illustrates a configuration in which a plurality of adjacent points on the same plane are short-circuited, a plurality of non-adjacent points may be short-circuited. For example, a short bar that is not a straight line may be short-circuited, or the short bar may be arranged on a surface different from the antenna as a two-layer structure, and two or more points separated by interlayer conduction may be short-circuited.

  In this manner, in the antenna 301, the short circuit member 331 is provided so as to short-circuit a plurality of different points in the meandering radiating element 315, and the number of conductive paths having different lengths is increased. The number of resonance frequencies (resonance points) can be increased. Thereby, the VSWR characteristic of the antenna 301 in the use band can be improved.

  Here, when the antenna is mounted on a conductor member, it is affected by the conductor member, so that the use band (for example, 470 MHz to 770 MHz for a terrestrial digital broadcast antenna for Japan, or a terrestrial digital broadcast antenna for North America). VSWR characteristics at 470 MHz to 860 MH and 470 to 890 MHz for European terrestrial digital broadcasting antennas may deteriorate (VSWR value increases).

  In such a case, as shown in the antenna 301 of FIG. 7, in the meandering radiating element 315, by providing a short-circuit member 331 so as to short-circuit a plurality of different points, a VSWR characteristic in the use band is obtained. Deterioration (increase in VSWR value) can be suppressed. That is, in consideration of the influence from the conductor member, the position where the short-circuit member 331 short-circuits in the radiating element 315 is determined in the state where the dummy conductive member is disposed in the vicinity of the radiating element 315, and the short-circuit member 331 is disposed. As a result, the number of conductive paths having different lengths increases and the resonance frequency of the antenna 301 increases. As a result, even when the antenna 301 is mounted on a conductor member, it is possible to suppress deterioration of the VSWR characteristics (increase in VSWR value) in the use band due to the influence of the conductor member.

  In the antenna device 10 shown in FIG. 6, the short-circuit member 231 is arranged in the meandering radiation portion 212 as the short-circuit member 331 as described above. Determination of the position and location which arrange | positions the short circuit member 231 is performed as follows, for example.

  The arrangement of the short-circuit member 231 is smaller than that in the case where the short-circuit member 231 is not disposed in a state where the radiation element 11 is disposed on the metal plate via the dielectric and in each frequency within the use band. Decide as follows. More preferably, in a state where the radiating element 11 is disposed on the metal plate via a dielectric, the VSWR value at each frequency in the use band is determined to be 3.5 or less.

  More specifically, the short-circuit member 231 is temporarily placed on the radiation element 11 disposed on the dummy metal plate via the dielectric, and then the short-circuit member 231 is moved while monitoring the VSWR value in the use band. . And when the position where VSWR value becomes smaller than the case where the short circuit member is not arrange | positioned in each frequency in a use band is found, the short circuit member 231 is fixed to the position. On the other hand, when the position where the VSWR value becomes smaller than the case where the short-circuit member is not arranged at each frequency in the use band cannot be found, the above-described trial is performed while replacing the short-circuit member 231 to be used with one having a different shape or size. repeat.

  The short-circuit member 231 is to short-circuit predetermined positions of the radiating element 11, and for example, a conductive material such as a metal material can be used. For example, the short-circuit member 231 directly contacts the radiating element 11 to short-circuit the radiating element 11.

  Here, the experimental results of examining the relationship between the presence / absence of the short-circuit member 231 and the VSWR characteristics will be described below.

In this experiment, an antenna device 401 (radiating element) is mounted on a metal plate 403 as a conductor member of 350 mm × 250 mm via a dielectric layer 402 as shown in FIG. . The dielectric layer 402 will be described later.

  As the antenna device 401, the antenna device 10 shown in FIG. 6 and the antenna 501 shown in FIG. 9 were used, and the VSWR characteristics were measured for each of them. The antenna 501 in FIG. 9 has the same configuration as the antenna device 10 in FIG. 6 except that the short-circuit member 231 provided in the antenna device 10 in FIG. 6 is not provided.

FIG. 10 is a graph showing measurement results of the VSWR characteristics of the antenna device 10 and the antenna 501. In FIG. 10, the graph “with a short-circuit member” is the measurement result of the antenna device 10, and the graph “without a short-circuit member” is the measurement result of the antenna 501. At the time of this measurement, the thickness d of the dielectric layer 402 was 5 mm, and the relative dielectric constant ε _r was 1.

  From the experimental results shown in FIG. 10, the short circuit member 231 is arranged in the antenna device 10 to cause a short circuit, so that the VSWR is 3.5 in the band of 800 MHz or less in the terrestrial digital television band (470 MHz to 770 MHz). It can be seen that

  On the other hand, in the case of the antenna 501 having no short-circuit member, it can be seen that the VSWR can be suppressed to 3.5 or less in the band of 650 MHz to 750 MHz.

  However, also in the antenna 501, since VSWR is suppressed to 3.5 or less in the frequency band of about 650 MHz to 750 MHz, good transmission / reception can be performed in this frequency band. This is considered to be an effect of the antenna 501 including the radiating element 11 having a meander-shaped conductive path.

  In the case of the antenna 501, a favorable frequency band is about 650 MHz to 750 MHz, but this is merely an example. That is, depending on the meander shape design, the value and range of the frequency at which the VSWR is 3.5 or less can be changed variously. Therefore, depending on the frequency band used, the short-circuit member may not be provided.

Effect of Dielectric Thickness As shown in FIG. 8, the inventors of the present application provide a dielectric layer 402 between the antenna device 401 and a metal plate 403 as a conductor member, whereby the antenna device 401 and the conductor are provided. It has been found that an antenna having a VSWR characteristic that can withstand practical use can be realized even if the distance to the member (metal plate 403) is reduced to a few millimeters. At this time, the relative dielectric constant ε _r of the dielectric layer 402 is preferably set to 1 or more and 10 or less. This is because if the relative dielectric constant ε _r is greater than 10, the reduction in radiation efficiency cannot be ignored.

  FIG. 11 shows the measurement results of the VSWR characteristics of the antenna device 401 at each thickness d when the thickness d of the dielectric layer 402 is changed. Here, the antenna device 10 of FIG. 6 is used as the antenna device 401.

  Further, as the thickness d, four conditions of d = infinity (∞), d = 5 mm, d = 2 mm, d = 0 mm were prepared. Note that d = infinity is a condition that means that the distance between the antenna device 10 and the metal plate 403 is infinite, that is, the state where the metal plate 403 does not exist. Further, d = 0 mm is a condition that means a situation in which the antenna device 10 is mounted so as to contact the metal plate 403 through an insulating member such as an insulating film that is as thin as possible. That is, d = 0 mm indicates the distance in which the antenna device 10 and the metal plate 403 are as close as possible without the conductor portion of the antenna device 10 and the metal plate 403 being in direct contact.

  As shown in FIG. 11, it can be seen that VSWR can be suppressed to 3.5 or less in the band of 470 MHz to 770 MHz under the two conditions of d = infinity and d = 5 mm. Further, even when d = 2 mm, it can be seen that the VSWR can be suppressed to 3.5 or less in the band of 470 MHz to 770 MHz except for the band near 670 MHz. From this, the following can be said.

  If d = infinity, that is, if the antenna device 10 is not mounted on the metal plate 403, the antenna device 10 is not affected by the metal plate 403. In other words, if the antenna device 10 approaches the metal plate 403 gradually from infinity to the metal plate 403, the closer to the metal plate 403, the stronger the influence from the metal plate 403 should be.

  Therefore, what can be said from the results of FIG. 11 is that the thickness d of the dielectric layer 402 between the antenna device 10 and the metal plate 403, that is, the distance between the antenna device 10 and the metal plate 403 is 5 mm or more. In other words, it can be said that VSWR can be suppressed to 3.5 or less in the band of 470 MHz to 770 MHz. Further, if the distance between the antenna device 10 and the metal plate 403 is 2 mm or more, it can be said that the VSWR can be suppressed to 3.5 or less in the band of 470 MHz to 770 MHz except for some exceptional bands.

FIG. 11 shows a case where an antenna base material having a relative dielectric constant ε _r of about 2 to 3 and a thickness of 1 mm or less is used. Isolation other than the base material, that is, the thickness of the dielectric layer 402 is _expressed as a relative dielectric constant. The characteristic is shown when the material is provided with a material of ε _r = about 1 (such as polystyrene foam).

Therefore, in the characteristics shown in FIG. 11, when the thickness d = 2 mm, the VSWR deteriorates in the vicinity of 670 MH, but in the present invention, the VSWR in the 670 MHz band does not necessarily deteriorate. This is characteristic shown in FIG. 11, the short circuit member or meander, the dielectric constant epsilon _r and thickness of the antenna base, be adjusted by optimizing the relative permittivity epsilon _r and the like of the dielectric layer 402 Because it is possible.

FIG. 12 is a graph showing a radiation pattern in the 550 MHz band of the antenna device 10 shown in FIG. 12A shows a radiation pattern on the xy plane, FIG. 12B shows a radiation pattern on the yz plane, and FIG. 12C shows a radiation pattern on the zx plane. At this time, the thickness d of the dielectric layer 402 was 5 mm, and the relative dielectric constant ε _r was 1. In addition, Eθ shown in FIG. 12 represents the radiation power of the antenna with respect to the vertical polarization V, Eφ represents the radiation power of the antenna with respect to the horizontal polarization H, and Etotal represents the total radiation power of the antenna.

  As can be seen from FIG. 12, the radiation omnidirectionality is realized in any of the radiation pattern on the xy plane, the radiation pattern on the yz plane, and the radiation pattern on the zx plane.

<Modification Example of Antenna Device [1]>
FIG. 13 shows an antenna device 10 a that is a modification of the antenna device 10. Hereinafter, the detailed description will be given of the parts different from the antenna device 10, and the description of the same parts will be omitted.

  The size of the antenna device 10a is 83 mm in the left-right direction (X-axis direction) in FIG. 13 and 56 mm in the vertical direction (Z-axis direction).

  In the winding part 211a, a power feeding part 222a is formed on each of the two root parts 225a and 226a of the radiating element 11a. Each of the two root portions 225a and 226a is supplied with power from a power supply line 221a connected to the power supply portion 222a.

  The first root portion 225a includes a first straight portion 225a1 and a first bent portion corresponding to the first straight portion 225o1 and the first bent portion 225o2 of the first root portion 225 shown in FIG. 225a2 (rear end straight portion). Similarly, the second root portion 226a includes the second straight portion 226a1 and the second bent portion corresponding to the second straight portion 226o1 and the second bent portion 226o2 of the second root portion 226 shown in FIG. It has a portion 226a2 (rear end straight portion).

  Unlike the power supply line 221 of the first embodiment, the power supply line 221a extends in the negative direction of the Z axis in FIG.

  For this reason, the direction in which the two root portions 225a and 226a of the radiating element 11a are taken out is orthogonal to the direction in which the feeder line 221 extends.

  The first wide portion 213a is positioned below the feeder line 221a, and the line width (the length in the X-axis direction) of the portion overlapping the feeder line 221a is the winding portion 211a and the radiating portion of the radiating element 11a. It is wider than the line width of the portion constituting 212a.

  Unlike FIG. 13, the power supply line 221 a may extend from the power supply unit 222 a in the negative direction of the X axis.

  Further, the short-circuit member 231a and the short-circuit member 232a are disposed in the meander shape of the radiating portion 212a. The roles of the short-circuit member 231a and the short-circuit member 232a are the same as described above.

  Next, the difference in the VSWR characteristics depending on the presence / absence of the short-circuit members 231a and 232a will be described below.

Effect of presence or absence of short-circuit member of modification [1] As described above, antenna device 401 (radiating element) is mounted on 350 mm × 250 mm metal plate 403 via dielectric layer 402 as shown in FIG. did.

  As the antenna device 401, the antenna device 10a shown in FIG. 13, the antenna 502 shown in FIG. 14, and the antenna 503 shown in FIG. 15 were used, and the VSWR characteristics were measured for each of them. The antenna 502 of FIG. 14 has the same configuration as the antenna device 10a of FIG. 13 except that the short-circuit member 232a of FIG. 13 is not disposed in the meander shape portion of the radiating portion 212a. Further, the antenna 503 in FIG. 12 has the same configuration as the antenna device 10a in FIG. 13 except that the short-circuit members 231a and 232a in FIG. 13 are not arranged in the meander shape portion of the radiating portion 212a.

In FIG. 16, the measurement result of each VSWR characteristic of the antenna device 10a, the antenna 502, and the antenna 503 is shown. In FIG. 16, the graph “with short circuit member” is the measurement result of the antenna device 10 a, the graph “without short circuit member” is the measurement result of the antenna 503, and the graph “without second short circuit member” is the antenna 502. It is a measurement result. At the time of this measurement, the thickness d of the dielectric layer 402 was 5 mm, and the relative dielectric constant ε _r was 1.

  As shown in FIG. 16, first, from the graph of “no second short-circuit member”, the short-circuit member 231a is arranged to cause a short-circuit, thereby generating a low frequency in the terrestrial digital television band (470 MHz to 770 MHz). It can be seen that VSWR can be suppressed to 3.5 or less in the band.

  Furthermore, from the graph of “with short circuit member”, by arranging the short circuit member 232a and causing a short circuit, the VSWR is suppressed to 3.5 or less even in the high frequency band of the terrestrial digital television band (470 MHz to 770 MHz). You can see that

  However, from the graph of “no short-circuit member”, as described above, in the antenna 503, the VSWR is suppressed to 3.5 or less in the frequency band of about 550 MHz to 620 MHz and the frequency band of about 680 MHz to 770 MHz. Good transmission and reception can be performed in this frequency band. This is considered to be due to the fact that the antenna 503 includes the radiating element 11a having a meander-shaped conductive path. Therefore, the number of short-circuit members installed, including zero, can be changed depending on the frequency band used.

Effect of Dielectric Thickness of Modified Example [1] FIG. 17 shows the measurement results of the VSWR characteristics of the antenna device 401 at each thickness d when the thickness d of the dielectric layer 402 is changed. Here, the antenna device 10 a in FIG. 13 is used as the antenna device 401.

  Further, as the thickness d, four conditions of d = infinity (∞), d = 5 mm, d = 2 mm, d = 0 mm were prepared.

  As shown in FIG. 17, it can be seen that VSWR can be suppressed to 3.1 or less in the 420 MHz to 920 MHz band under the two conditions of d = infinity and d = 5 mm.

  Further, it can be seen that VSWR can be suppressed to 3.5 or less in the band of 420 MHz to 870 MHz under the three conditions of d = infinity, d = 5 mm, and d = 2 mm.

  From this, it can be said that if the distance between the antenna device 10a and the metal plate 403 is 2 mm or more, the VSWR can be suppressed to 3.5 or less in the band of 420 MHz to 870 MHz.

  Here, FIG. 17 shows a case where an antenna base material having a relative dielectric constant εr of about 2 to 3 and a thickness of 1 mm or less is used, and the separation other than the base material, that is, the thickness d of the dielectric layer 402 is expressed as the relative dielectric constant. The characteristic is shown when the material is provided with a material having a ratio εr = about 1 (such as polystyrene foam).

  Even in the case of d = 0 mm, for example, in a frequency band near 450 MHz, a frequency band such as about 520 MHz to 690 MHz and about 750 MHz to 830 MHz, VSWR can be suppressed to 3.5 or less, and good transmission / reception can be performed. . Therefore, when the frequency band to be used may be limited to the characteristic frequency, the antenna device 10a including the meander-shaped radiating element 11 of the present invention is kept as far as possible while being insulated from the conductor surface. Can be approached.

FIG. 18 is a graph showing a radiation pattern in the 550 MHz band of the antenna device 10a shown in FIG. 18A shows a radiation pattern on the xy plane, FIG. 18B shows a radiation pattern on the yz plane, and FIG. 18C shows a radiation pattern on the yz plane. At this time, the thickness d of the dielectric layer 402 was 5 mm, and the relative dielectric constant ε _r was 1.

  As can be seen from FIG. 18, the radiation omnidirectionality is realized in any of the radiation pattern on the xy plane, the radiation pattern on the yz plane, and the radiation pattern on the zx plane.

<Modification Example of Antenna Device [2]>
A further modification of the antenna device will be described. FIG. 19 is a plan view of the antenna device 10b.

  The antenna device 10 shown in FIG. 6 and the antenna device 10b shown in FIG. 19 are different from the antenna device 10b shown in FIG. 19 in that a short-circuit member is provided on the side away from the feeding portion 222 of the radiating portion 212 having a meander shape. 231 'is provided. About others, it is the same as the antenna apparatus 10 of FIG.

  Similarly to the antenna device 10a of the modified example [1] shown in FIG. 13, the antenna device 10b of the modified example [2] has a bandwidth of 420 MHz to 870 MHz if the distance from the metal plate 403 is 2 mm or more. , The VSWR is suppressed to 3.5 or less, and radiation omnidirectionality is realized in any of the radiation pattern on the xy plane, the radiation pattern on the yz plane, and the radiation pattern on the zz plane.

  As described above, in the present embodiment, the antenna devices 10, 10 a, and 10 b having high sensitivity and no directivity are disposed inside the A pillar 1 a.

  Below, some specific examples of the arrangement position of the antenna apparatus 10 in this embodiment which arrange | positions the antenna apparatus 10 in A pillar 1a are given.

<Example 1 of arrangement of antenna device to pillar>
FIG. 20 is a cross-sectional view of the A pillar 1a shown in FIG. 2 taken along the cutting line HH ′.

  The A pillar 1a includes an interior material 13 made of an insulating material such as a synthetic resin and an exterior material 14 made of a conductor. The interior material 13 constitutes a wall portion inside the automobile 60 (FIG. 1), and the exterior material 14 constitutes the outer shell of the automobile 60.

  While the exterior material 14 has an arc shape in cross section, the interior material 13 has a cross sectional shape such as a straight cross section or a circular arc shape (in FIG. 20, a cross sectional shape in which short arc-shaped cross sections are continuous at both ends of the linear cross section. The A-pillar 1a includes the exterior material 14 in a state where the end of the cross section of the exterior material 14 and the end of the cross section of the interior material 13 are in contact with each other. The interior material 13 is connected to form a tubular shape (hollow structure).

  Note that the configuration of the A pillar 1a itself is the same in Arrangement Example 2 and later described later. As specific materials of the interior material 13 and the exterior material 14, well-known materials can be adopted.

  In the present arrangement example 1, a flat plate-like radiation element 11 is formed along the cavity-side surface 13a of the interior material 13 in the A pillar 1a (in this arrangement example 1, the antenna device 10 includes the flat plate-like radiation element 11). Is attached. That is, the antenna device 10 is disposed so that the cavity-side surface 13a and the surface of the flat radiation element 11 are substantially parallel.

  Here, in the case of the configuration shown in FIG. 20, the flat radiating element 11 needs to be arranged away from the exterior material 14.

The distance L (hereinafter referred to as the separation distance) L is set to 2 mm, for example, in consideration of the VSWR characteristics, as will be described in detail later. However, the separation distance L is not limited to 2 mm, and may be 2 mm or more, which is a separation distance that can suppress VSWR to 3.5 or less.
The distance L should just be provided 2 mm or more.

  Moreover, since the antenna device 10 has flexibility as described above, even if the shape of the inner surface of the cavity-side surface 13a is curved, it can be easily pasted as a shape along the same. it can. If it is attached along a curved surface having a curvature radius R of 5 mm or more, the antenna device 10 can maintain good characteristics.

  Although there is no restriction | limiting in particular as the attachment method of the antenna apparatus 10, If a flexible adhesive tape etc. with thickness of 2 mm or more are used as a sheet-like base material holding the antenna apparatus 10, for example, the cavity side surface 13a The antenna device 10 can be adhered along the inner surface shape of the cavity-side surface 13a and the shape of the rib even when a protruding object such as a rib is present at the attachment location.

  However, it is not limited to the above-mentioned sticking, and it is also possible to attach to the cavity side surface 13a using attachment parts such as screws.

  In the present arrangement example 1, the antenna device 10 is disposed on the cavity-side surface 13a of the interior material 13, but instead, the antenna device 10 may be disposed on the interior surface of the interior material 13. . In that case, a protective layer for protecting the flat radiation element 11 is provided on the outermost layer. However, since it is not visually recognized if it is the cavity side surface 13a of the interior material 13, it is preferable to arrange the antenna device 10 on the cavity side surface 13a.

  As described above, in the present arrangement example 1, the antenna device 10 is disposed on the cavity side surface 13a of the interior material 13. In general, an automotive interior material is formed of a dielectric material such as a resin. Therefore, the surface of the interior material for a moving body is a place that is not easily affected by a conductor, and is suitable as a place for installing an antenna device.

  In particular, in the above configuration, the flat plate-like radiating element 11 is arranged away from the surface of the exterior material 14 made of a conductive material. According to this configuration, it is possible to avoid deterioration of the antenna characteristics due to the influence of the conductor. Specifically, the separation distance L of the flat radiation element 11 with respect to the exterior material 14 is at least 2 mm. According to this, even when the antenna is mounted near the conductor, a usable frequency band in which the VSWR value is suppressed to 3.5 or less can be expressed.

  Moreover, since the flat radiation | emission element 11 has flexibility, even if it is the cavity side surface 13a of the curved interior material 13, it can attach easily along this. Specifically, the flat radiating element can be attached along a curved surface with a curvature radius of 5 mm or more along the surface shape of the interior material, and can be attached with a curvature radius of 5 mm or more. Characteristics can be maintained.

  The antenna performance in the aspect of this arrangement example 1 will be described later (operational effects of this embodiment).

<Example 2 of arrangement of antenna device to pillar>
FIG. 21 is a cross-sectional view taken along the arrow line when the A pillar 1a shown in FIG.

  In the present arrangement example 2, the antenna device 10 is disposed on the inner surface 14a of the exterior member 14 formed of a conductor in the A pillar 1a.

  Since the inner surface 14a of the exterior material 14 is made of a conductor, in the present arrangement example 2, the flat plate-shaped radiating element 11 is disposed away from the inner surface 14a.

  Although the details will be described later, the separation distance L is set to 2 mm, for example, in consideration of the VSWR characteristics. However, the separation distance L is not limited to 2 mm, and may be 2 mm or more, which is a separation distance that can suppress VSWR to 3.5 or less.

  In this embodiment, a sheet-like insulator 12 having a thickness corresponding to the separation distance L is placed on the inner surface 14 a of the exterior material 14, and the flat radiating element 11 is placed on the sheet-like insulator 12. Install it.

  As described above, the antenna device 10 can be disposed even in a relatively narrow space because the outer surface 14a may be separated from the inner surface 14a by 2 mm or more. Therefore, the antenna device 10 requires less space for installation.

  In the second arrangement example, the separation distance L is ensured by using the sheet-like insulator 12. However, the present invention is not limited to this, and a configuration as shown in FIG. FIG. 21 is a modification of FIG. In FIG. 21, a predetermined number of spacers (insulators) 15 having a thickness corresponding to the separation distance L are installed at appropriate positions on the inner surface 14a, and a flat plate-like radiation element 11 is installed on the spacers 15 to The structure which fixes the flat radiation | emission element 11 to the spacer 15 with the attachment components 16 of these can be considered.

  In the second arrangement example, the antenna device 10 is disposed on the inner surface 14 a of the exterior material 14. Alternatively, the antenna device 10 may be disposed on the outer surface of the exterior material 14. In that case, a protective layer for protecting the flat radiation element 11 is provided on the outermost layer. However, since it is not visually recognized if it is the inner surface 14a of the exterior material 14, it is preferable to arrange the antenna device 10 on the inner surface 14a.

  Here, a typical example of an exterior material including a conductive material layer is a metal that is widely used as a material for forming a body of an automobile, an airplane, a train, a ship, or the like, provided that it has rigidity required for the body. The conductive shell material may be included in the category of the outer shell without being limited to the metal.

  As described above, in the present arrangement example 2, the antenna device 10 is disposed on the inner surface 14 a of the exterior material 14. In this structure, the separation distance of the flat radiation element 11 with respect to the front surface or the back surface of the exterior material is at least 2 mm. Thereby, even when the antenna device is mounted near the conductor, a usable frequency band in which the VSWR value is suppressed to 3.5 or less can be expressed.

  Moreover, a dielectric layer can be interposed between the exterior material 14 and the flat plate-like radiation element 11, and the flat plate-like radiation element 11 can be fixed to the dielectric layer. Accordingly, since the dielectric layer is interposed between the radiating element and the outer shell, when the antenna device is provided on a metal member such as a car body of an automobile, the dielectric layer suppresses an adverse effect from the metal member. Can do. Thereby, the antenna apparatus can maintain a favorable VSWR characteristic.

  In addition, using a cover member that covers a part of the surface of the exterior material, a space portion is formed between the surface of the exterior material on the inner side of the cover member, and a flat plate is formed along the inner surface of the cover member. The radiating element 11 may be fixed. Accordingly, when the antenna device is installed on the surface of the outer shell of the moving body, the cover member that is indispensable from the viewpoint of waterproofing and protection is effectively used as the support member that suppresses the adverse effect received from the conductive material layer. be able to. In this configuration, an air layer is interposed as a dielectric layer between the radiating element and the outer shell. Thereby, the antenna apparatus can maintain a favorable VSWR characteristic.

  Further, in the second arrangement example, the flat radiation element 11 may be curved. In this case, if the radius of curvature is 5 mm or more, the antenna device 10 can maintain good characteristics.

  The antenna performance in the aspect of this arrangement example 2 will be described later (operational effects of this embodiment).

<Example 3 of arrangement of antenna device to pillar>
FIG. 23 is a view showing a part of the A pillar 1a. In this arrangement example 3, a wire harness 17 having the antenna device 10 passes through a cylindrical hollow portion formed by the exterior material 14 and the interior material 13. That is, in this arrangement example 3, the antenna integrated harness is passed through the A pillar 1a, and the height of the mounting position of the antenna device 10 is set to 1/3 or more and 2/3 or less of the height of the A pillar 1a. is there.

  FIG. 24 is a perspective view of an antenna integrated wire harness 17. FIG. 25 is a cross-sectional view of the wire harness 17 shown in FIG. 24 taken along the cutting line SS ′.

  The wire harness 17 is configured by bundling a plurality of electric wires 33, and the flat radiating element 11 is wound around the surface layer of the wire harness 17.

  As shown in FIG. 25, the wire harness 17 includes a plurality of electric wires 33, a tape member 32 for bundling these electric wires 33, and a shield material 31.

  Each of the plurality of electric wires 33 includes a conductive wire portion and an insulating portion that covers the conductive wire portion and insulates the conductive wire portions from each other.

  The tape member 32 is not particularly limited as long as it can bundle the electric wires 33, but it is preferable to select a material capable of exhibiting desirable performance as a wire harness. For example, it is preferable to select a material having excellent wear resistance, heat resistance, adhesion, and the like.

  The tape member 32 is preferably made of an insulating material. This is because the insulation between the conductor portion of the electric wire 33 and the antenna device 10 can be maintained even when the covering of the electric wire 33 is damaged, and the damaged electric wire 33 adversely affects the antenna performance. Because there is no.

  In this embodiment, a tape member is used as a means for bundling a plurality of electric wires 33. However, the present invention is not limited to this, and a conventionally known material for bundling electric wires can be used.

  The outer surface of the wire harness 17 bundled by the tape member 32 is covered with a shield material 31.

  The shield material 31 plays a role of shielding the bundled electric wires 33 and is made of a conductive material. The shield material 31 can block noise from the group of electric wires 33 and can block the influence of the noise on the antenna device 10 attached to the exterior side of the shield material 31. In addition, the shielding material 31 does not need to cover all the outer surfaces of the wire harness 17, and may cover only the area | region where the antenna apparatus 10 is attached, and its periphery.

  Note that both the tape member 32 and the shield material 31 need not have a width equal to the entire length of the wire harness 17, and may be wound while partially overlapping a tape having a width shorter than the entire length.

  Further, the wire harness 17 shown in FIG. 24 has a plurality of electric wires 33 exposed at the tip, but the present invention is not limited to this, and a component such as a connector or other electronic device is connected to the tip. It may be.

  Moreover, although this embodiment demonstrates the structure which installed the antenna apparatus 10 in the one wire harness 17, this invention is not limited to this, The wire harnesses 17 are bundled and the surface bundled is bundled. The structure which installed the antenna apparatus 10 may be sufficient.

  The antenna device 10 is disposed so as to cover a part of the surface of the wire harness 17 as shown in FIG. 24, specifically, along the surface of the shield material 31 as shown in FIG. Yes.

  The surface (also referred to as a side surface) of the wire harness 17 used in the present embodiment, that is, the surface of the shield material 31 is a curved surface. Therefore, the antenna device 10 covering a part of the surface is also curved as shown in FIG. 24 and is configured to be wound around the surface of the shield material 31.

  The antenna device 10 includes a dielectric portion 12 and a flat plate-like radiating element 11, and the dielectric portion 12 is arranged between the shield material 31 and the flat plate-like radiating element 11. .

  The dielectric portion 12 is made of a dielectric material, and is provided to insulate between the shield material 31 and the flat radiating element 11. The shield material 31 and the flat plate-like radiation element 11 are separated by a predetermined distance by the dielectric portion 12. Specifically, as will be described later, it is only necessary that the shield material 31 that is a conductive material and the flat radiation element 11 be separated by at least 2 mm.

  The structure of the dielectric part 12 is not particularly limited as long as it functions as a spacer that holds the shield member 31 and the flat radiation element 11 at a predetermined interval. For example, a two-dimensional planar dielectric layer that covers the entire surface of the flat radiating element 11 may be used, or a part of the flat radiating element 11 may be covered. Or a through-hole and a recessed part may be provided, and you may comprise from several protrusion body which has the same protrusion height as a predetermined | prescribed space | interval.

  In the antenna device 10 wound around the surface of the shield material 31 of the wire harness 17, both end portions of the flat radiating element 11 may not overlap each other by winding. For example, when the outer circumference (circumference) of the wire harness 17 (shield material 31) is 120 mm, the length along the outer circumference of the shield material 31 in the flat radiation element 11 of the antenna device 10 wound around the wire harness 17 (120 mm) is 120 mm. If it is less than.

  In the case of the flat plate-like radiating element 11 curved in this way, the radius of curvature R is preferably 5 mm or more. If it is attached along a curved surface having a radius of curvature R of 5 mm or more, good antenna characteristics can be maintained.

  Although there is no restriction | limiting in particular in the attachment method of the antenna apparatus 10 to the wire harness 17 (shield material 31), Adhesion using an adhesive agent, fixation using the nail | claw for fixing, etc. can be mentioned.

  Further, as shown in FIG. 24, the power supply line 221 connected to the power supply unit 222 of the flat radiating element 11 is bundled together with the plurality of electric wires 33 of the wire harness 17 in the vicinity of the power supply unit 222. 17 is arranged together with a plurality of electric wires 33. In FIG. 24, the hole 18 is provided in the vicinity of the power feeding part 222 of the tape member 32 and the shield material 31, and the power feeding line 221 is drawn into the wire harness 17 from the hole 34 and bundled with the plurality of electric wires 33. Yes. Note that the method of drawing the power supply line 221 into the wire harness 17 is not limited to this. In FIG. 24, the inside of the wire harness 17 extends in a direction in which the power supply line 221 is separated from the radiating element 11, but the extending direction may be the opposite direction.

  In addition, when the insulating material is provided in the exterior of the shield material 31 of the wire harness 17 with a thickness of at least 2 mm, the antenna device 10 does not include the dielectric portion 12 and is flat on the surface of the insulating material. The radiating element 11 may be formed.

  For convenience of explanation, FIG. 24 shows a configuration in which the antenna device 10 is disposed in the outermost layer, but an exterior member that covers the wire harness 17 together with the antenna device 10 may be provided.

  Moreover, in this arrangement example 3, the antenna device 10 is attached to the shield material 31, but the present invention is not limited to this, and further includes an exterior member that covers the surface of the wire harness (shield material 31). The radiating element 11 may be formed on the surface of the exterior member facing the shield material 31. This point will be described.

  FIG. 26 is a cross-sectional view of the wire harness, similar to FIG. In the wire harness 17a illustrated in FIG. 26, an exterior member 30 is disposed so as to cover the antenna device 10.

  In addition to protecting the antenna device 10 from external impact, the exterior member 30 prevents a conductor from inadvertently approaching the antenna device 10. Specifically, the exterior member 30 can be made of a plastic material or the like.

  As a method for attaching the exterior member 30, for example, a cleaving portion is provided along the longitudinal direction of the exterior member made of a plastic material, and after mounting the antenna device 10, the cleaving portion of the exterior member is cleaved, and the wire harness 17 and The antenna device 10 may be covered.

  In FIG. 26, the exterior member 30 covers the entire circumference of the wire harness 17 and the antenna device 10, but the present invention is not limited to this, and at least the antenna device 10 is configured to be covered. May be.

  As described above, the configuration of the present arrangement example 3 is a configuration in which the antenna device 10 (the flat radiating element 11) is wound around the wire harness 17, and the antenna device 10 specifies the A pillar 1a illustrated in FIG. Located in the area.

  Since the flat radiating element 11 has a flat plate shape along the surface of the shield material 31, a space for installation is very small. For example, if the radiating element is a conductor having a thickness of 1 mm as described later, the diameter of the wire harness only needs to be increased by about 2 mm. Therefore, in the case of the present invention, it can be installed even in a narrow space that could not be installed with an antenna device having a conventional configuration.

  And by providing the dielectric portion 12 on the surface side of the shield material 31 in the flat radiation element 11, the flat radiation element 11 and the wire 33 of the wire harness are insulated, or A state close to insulation can be realized.

  Thereby, the flat radiation element 11 can be arrange | positioned in the vicinity of the electric wire 33 of the wire harness 17, and even if arrange | positioned, the characteristic of a flat radiation element is not disturbed and it shows a favorable antenna characteristic Is possible.

  However, instead of the above configuration, if the surface of the shield material 31 is made of a dielectric, the flat plate-shaped radiating element 11 may be arranged directly on the surface of the dielectric. Even with this configuration, the radiating element 11 is insulated from or close to insulation from the electric wire 33, and thus the characteristics of the radiating element 11 are not hindered by the electric wire 33 and can exhibit good antenna characteristics. It is.

  The flat radiation element 11 has a shape along the curved surface of the shield material 31. According to this, the antenna device can be disposed even in a narrow space. Specifically, if the radius of curvature of the curved surface of the radiating element 11 is 5 mm or more, good characteristics can be maintained.

  The antenna performance in the arrangement example 3 will be described in the following <Effects of this embodiment>.

<Operational effects of this embodiment>
In this embodiment, as shown in FIG. 4, the height of the mounting position of the antenna device 10 with respect to the lower end of the A pillar 1a is set to 2/3 or less of the height of the upper end of the A pillar 1a with respect to the lower end of the A pillar 1a. The configuration is adopted.

  As described above, the roof 61 is generally configured using a conductive material and has a structure extending in the horizontal direction. However, the carrier wave of terrestrial digital broadcasting is incident from the horizontal direction. Since it is horizontally polarized, it is greatly attenuated by the action of the roof 61. FIG. 27 is a diagram for explaining this point. FIG. 27 shows the B pillar 1b shown in FIG. 1 and the roof 61 that extends over the B pillar 1b, and schematically shows the received power when the antenna device 10 is disposed at each position. The values shown in FIG. 27 are the relative values of the received power, and 0 dB = 51 dBm (based on the maximum received power when arranged in the B pillar 1b). According to FIG. 27, regarding the case where the antenna device 10 is arranged on the roof 61, the reception power decreases as the antenna device 10 moves away from the window, that is, the electromagnetic wave propagating along the roof 61 is attenuated by the action of the roof 61. I understand that

  FIG. 28 shows the received power when the A pillar 1a is divided into three equal parts as described above, and the antenna device 10 is provided in each of the pillar upper part, pillar central part, and pillar lower part. The values shown in FIG. 28 are the relative values of the reception power as in FIG. 27, and are substantially the same as the values shown in FIG. As shown in FIG. 28, when the antenna device 10 is arranged at the pillar central portion among the pillar upper portion, the pillar central portion, and the pillar lower portion, the reception power becomes the strongest. This is because the electromagnetic wave that has entered the interior of the vehicle from each window can reach the center of the pillar without being attenuated by the metal members constituting the roof 61 and the body 62.

  In FIG. 28, the antenna device 10 arranged at the lower part of the pillar has a higher reception power following the pillar center part. This is because the lower part of the pillar is farthest from the roof 61, and electromagnetic waves that have entered the vehicle from each window can reach the lower part of the pillar without being attenuated by the action of the roof 61. However, since it is attenuated by the metal member constituting the body 62 (FIG. 1), the received power is lower than that in the case where the body 62 is arranged at the center.

  Further, based on FIG. 29, the correlation between the position of the pillar and the received power will be described. In each of FIG. 29, the upper side of the drawing is the front of the automobile 60, and the lower side of the drawing is the rear of the automobile 60. FIG. 29 is a diagram schematically showing the difference in received power depending on the direction of electromagnetic waves. FIG. 29A shows a case where the antenna device 10 is arranged on the upper side of the A pillar on the left side in the traveling direction. FIG. 29B shows a case where the antenna device 10 is arranged at the center of the pillar, and FIG. 29C shows a case where the antenna device 10 is arranged below the pillar. The values shown in FIG. 29 are the relative values of the reception power as in FIGS. 27 and 28, and are substantially the same as the values shown in FIG.

  In the case of the antenna device 10 shown in FIG. 29A, the electromagnetic wave from the rear right side is greatly attenuated, and the reception power is indicated by −10 dB. On the other hand, in the case of the antenna device 10 shown in (c) of FIG. 29, the reception power for the electromagnetic wave from the right rear is similarly represented by −7 dB. This also shows that attenuation of electromagnetic waves can be suppressed more in the lower part of the pillar than in the upper part of the pillar.

  Furthermore, in the case of the antenna device 10 shown in FIG. 29 (b), it can be seen that the reception power with respect to the electromagnetic wave from the right rear is −5 dB, and the attenuation of the electromagnetic wave can be further suppressed than the lower part of the pillar.

  From the above, the antenna device 10 has the height of the mounting position of the antenna device 10 with respect to the lower ends of the pillars 1a to 1c as 2/3 or less of the height of the upper ends of the pillars 1a to 1c with respect to the lower ends of the pillars 1a to 1c. It is preferable to do. As a result, the antenna device 10 can be mounted away from the roof 61, and thus the reception power can be increased. And if it arrange | positions in the intermediate part (central part) of the pillars 1a-1c which are separated from the roof 61 and the body 62, and the vicinity also has a window and is open comparatively widely, attenuation of electromagnetic waves will be more. Since it can suppress further, it is more preferable.

  In the present embodiment, the antenna device is disposed on the pillars 1a to 1c that support the roof 61. However, the present invention is not limited to this, and a member that exists between adjacent windows. If the member is located in the region corresponding to two of the regions divided by three equal heights from the body to the roof, preferably in the region corresponding to one in the middle. The antenna device 10 can be mounted in the area. An example of such a member is a seat belt upper fixture 40 as shown in FIG. 30 and a member 41 in the vicinity of the A pillar 1a as shown in FIG.

[Embodiment 2]
Another embodiment according to the present invention will be described below with reference to FIG. In addition, in this embodiment, in order to explain a difference from the first embodiment, for the sake of convenience of explanation, members having the same functions as the members described in the first embodiment are denoted by the same member numbers, and the description thereof. Is omitted.

  In the first embodiment, the antenna device is attached to the pillars 1a to 1c or members (FIGS. 30 and 31) disposed in the vicinity of the pillar. On the other hand, in this embodiment, the antenna device is attached to a member disposed around the window.

  FIG. 32 is a diagram showing the antenna device arrangement position of the present embodiment. In the present embodiment, the antenna device 10 is attached to members disposed around the rear window 632.

  Here, the “members arranged around the window” correspond to members constituting the window frame. The automobile 60 of the present embodiment is a so-called hatchback type vehicle type, and has a structure in which a back door 68 (intervening portion) including a rear window 632 at the rear of the rear seat is opened and closed. And in this embodiment, the antenna apparatus 10 is arrange | positioned in the side part (interposition part) of the rear window 632 in the back door 68 shown in FIG. The side portion is in the vicinity of the C pillar 1c and has a predetermined length along the length direction of the C pillar 1c. In addition, the lateral portion has a hollow structure so that the antenna device can be disposed in the internal space.

  In the present embodiment, the antenna device 10 is attached to the side portion of the back door 68. Specifically, the height of the mounting position of the antenna device (the height of the mounting position of the antenna device with respect to the lower end of the side portion) is 2/3 or less of the height of the upper end of the side portion with respect to the lower end of the side portion. More preferably, it is 2/3 or less and 1/3 or more.

  Here, an upper end of the side portion is a boundary portion with the roof 61, and a lower end thereof is a boundary portion with the body 62.

  Also according to the configuration of the present embodiment, the electromagnetic waves that have entered the vehicle from each window can reach without being attenuated by the metal members that constitute the roof 61 and the body 62.

  The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

[Summary]
As described above, the mobile body according to the present invention is a mobile body in which the antenna device is mounted, and the mobile body is provided with a plurality of windows on the side surface and interposed between two adjacent windows. In the movable body including the interposition part extending from the roof part, the antenna device is a radiating element arranged in a two-dimensional plane, and includes a first feeding point including one end of the radiating element. A first root portion, a second root portion including the other end portion of the radiating element and provided with a second feeding point, and the first root portion and the second root portion are relayed. The antenna device is attached to the interposition portion, and the height of the mounting position of the antenna device with respect to the lower end of the interposition portion is set to the height of the interposition portion. 2/3 of the height of the upper end of the interposition part relative to the lower end Is lower, it is characterized in that.

  As described above, the antenna device includes a first feeding point provided at the first root portion of the radiating element and a second feeding point provided at the second root portion of the radiating element. Get power. For this reason, the antenna device functions as a loop antenna. Therefore, the sensitivity (gain) of the antenna device is higher than the sensitivity of the dipole antenna or monopole antenna. Further, in the antenna device, as described above, the intermediate portion of the radiating element is meandered. Therefore, the directivity of the antenna device is weaker than when the intermediate portion of the radiating element is not meandered. That is, the antenna device is an antenna device with high sensitivity and low directivity.

  For this reason, when the antenna device is attached to the interposition part, not only the electromagnetic wave coming from the direction in which the interposition part exists as seen from the inside of the mobile body but also the interposition seen from the inside of the mobile body. An electromagnetic wave that arrives from a direction other than the direction in which the unit exists and enters the inside of the moving body through a window provided on the side surface of the moving body can be received with high sensitivity.

  However, the roof portion is generally configured using a conductive material and has a structure that spreads in the horizontal direction. Therefore, electromagnetic waves that enter the inside of the moving body through the window provided on the side surface of the moving body and propagate along the roof portion are immediately attenuated by the action of the roof portion, and the inside of the moving body There is no deeper approach. For this reason, even in the antenna device, the height of the mounting position of the antenna device to the interposition part (height relative to the lower end of the interposition part) is 2 / of the height of the upper end of the interposition part relative to the lower end of the interposition part. If it is higher than 3, that is, if it is attached to a portion of the interposition part close to the roof part, the electromagnetic wave entering the inside of the moving body cannot be received with high sensitivity through the window provided on the side surface of the moving body. Sometimes.

  Therefore, in the present invention, as described above, the height of the mounting position of the antenna device with respect to the lower end of the interposition part is set to 2/3 or less of the height of the upper end of the interposition part with respect to the lower end of the interposition part. As a result, the electromagnetic wave arriving from any direction with respect to the moving body can be reliably received with high sensitivity. For this reason, it is not necessary to perform diversity reception.

  The two-dimensional surface is not limited to a flat surface, and may be a surface having a three-dimensional shape obtained by cutting a part of a curved surface such as a cylindrical surface, a spherical surface, a paraboloid, or a hyperboloid.

  Further, the roof portion refers to a portion of the outer shell of the moving body that is above the plurality of windows.

  Moreover, in one form of the moving body according to the present invention, the antenna device is attached to the interposition part, and the height of the mounting position of the antenna device with respect to the lower end of the interposition part is higher than the lower end of the interposition part. The height of the upper end of the interposition part is preferably 2/3 or less, and preferably 1/3 or more.

  According to said structure, the height of the attachment position of the said antenna apparatus is 2/3 or less of the height of the upper end of the said interposition part with respect to the lower end of the said interposition part, Comprising: It is 1/3 or more. That is, the antenna device is attached to an intermediate part of the interposition part. The intermediate portion is separated from the roof portion above the plurality of windows and from the body portion below the plurality of windows. Therefore, when the antenna device is attached to a part including the upper end (end on the roof part side) of the interposition part, or on the part including the lower end (end on the opposite side of the roof part side) of the interposition part. Compared with the case where an antenna device is attached, it is possible to receive with high sensitivity electromagnetic waves that have entered the mobile body through the window.

  Specifically, the interposition part is preferably a member constituting a window frame.

  According to said structure, since an antenna apparatus will be arrange | positioned in the vicinity of a window, electromagnetic waves can be received favorably.

  However, the present invention is not limited to this, and the interposition part may be a pillar that supports the roof.

  Even with the above configuration, the antenna device can be disposed in the vicinity of the window, so that electromagnetic waves can be received well.

  In one mode of the moving body according to the present invention, the interposition part has an exterior material provided with a conductive material layer, and the antenna device separates the radiating element from the conductive material layer. In the state, it is preferable to further include a support member that is a dielectric that is held along the front surface or the back surface of the exterior material.

  According to said structure, since the said radiation | emission element is spaced apart from the electroconductive material layer of the said exterior material, the characteristic of the said antenna apparatus does not deteriorate extremely by the effect | action of the said electroconductive material layer. Therefore, it is possible to attach a thin antenna device having high sensitivity and omnidirectional characteristics to the front or back surface of the exterior member including the conductive material layer of the moving body. That is, even in a narrow space such as a window frame or a pillar, an antenna device can be attached to exhibit a good antenna function.

  In one form of the moving body according to the present invention, the interposition part is a hollow structure in which a wire harness configured by bundling a plurality of electric wires is arranged in a hollow part, and the radiating element is a surface of the wire harness. It is preferable that the power supply line disposed along the first power supply point and connected to the first power supply point and the second power supply point is bundled with the plurality of electric wires.

  According to said structure, the two-dimensional planar radiation | emission element along the surface (namely, the surface along the length direction in a wire harness) of a wire harness is comprised, and transmission / reception of electromagnetic waves with a radiation element is carried out on the surface of a wire harness. Is possible.

  Moreover, since the said radiation element is distribute | arranged in the two-dimensional surface along the surface of a wire harness, the space for installation is very small. For example, if the radiating element is a conductor having a thickness of 1 mm as described later, the diameter of the wire harness only needs to be increased by about 2 mm. Therefore, it can be installed even in a narrow space that cannot be installed with an antenna device having a conventional configuration.

  Note that “the radiating element is disposed along the surface of the wire harness” not only means that the radiating element is (1) attached to the surface of the wire harness, but also as described later (2) The state which does not touch the surface of a wire harness directly is also included. Here, in (2), a state in which a dielectric is further attached to the surface of the wire harness and a radiating element is provided on the outer surface of the dielectric, and a dielectric along the surface of the wire harness. The state attached to the inner surface and the state embedded in the dielectric along the surface of the wire harness are included.

  In one form of the moving body according to the present invention, the interposition part has an interior material made of an insulating material, and the radiating element is disposed along the front surface or the back surface of the interior material. preferable.

  According to said structure, since the said flat radiation | emission element is arrange | positioned along the surface or back surface of the said interior material, installation space may be narrow.

  The present invention can be applied to a moving object including a broadcast wave receiving antenna. In particular, it is suitable for a mobile body equipped with an on-vehicle digital terrestrial broadcasting antenna.

1a A pillar (intervening part)
1b B pillar (intervening part)
1c C pillar (intervening part)
10, 10a, 10b Antenna device 11, 11a Radiating element 12 Insulator, dielectric portion 13 Interior material 13a Cavity side surface 14 Exterior material 14a Inner surface 15 Spacer 16 Mounting component 17, 17a Wire harness 30 Exterior member 31 Shield material 32 Tape Member 33 Electric wire 40 Upper fixture 41 Member 60 Automobile 61 Roof (roof part)
62 Body 64 Door for getting on and off 66 Trunk cover 67 Bonnet 68 Back door (intervening part)
211, 211a Winding part 212, 212a Radiation part 213, 213a, 213b First wide part 214 Second wide part 215, 215a, 315 Radiation element 221, 221a Feed line 222, 222a, 322 Feed part 225, 225a First 1 root portion 225a1 first straight portion 225a2 first bent portion 225o1 first straight portion 225o2 first bent portion 226, 226a second root portion 226a1 second straight portion 226a2 second bent portion 226o1 first 2 straight portions 226o2 second bent portions 231, 231 ′, 231a, 232a, 331 Short-circuit member (short-circuit portion)
400 Antenna device 401 Radiating element 402 Dielectric layer 403 Metal plate 630 Front window (window on side surface of moving object)
631 Side window (window on the side of the moving object)
632 Rear window (window on the side of the moving body)

Claims (7)

A moving body on which an antenna device is mounted, wherein a plurality of windows are provided on a side surface, and an intermediate portion extending from a roof portion of the moving body so as to be interposed between two adjacent windows. ,
The antenna device is a radiating element disposed in a two-dimensional plane, and includes a first root portion including one end portion of the radiating element and a first feeding point, and the other of the radiating elements. A radiating element including a second root portion including an end portion and provided with a second feeding point; and a meander-shaped intermediate portion that relays between the first root portion and the second root portion. ,
The antenna apparatus is attached to the interposition part, and the height of the mounting position of the antenna apparatus with respect to the lower end of the interposition part is 2/3 or less of the height of the upper end of the interposition part with respect to the lower end of the interposition part. A moving object characterized by that. The antenna apparatus is attached to the interposition part, and the height of the mounting position of the antenna apparatus with respect to the lower end of the interposition part is 2/3 of the height of the upper end of the interposition part with respect to the lower end of the interposition part. Less than or equal to 1/3,
The moving body according to claim 1. The interposition part is a member constituting a window frame.
The moving body according to claim 1 or 2, wherein The interposition part is a pillar that supports the roof.
The moving body according to claim 1 or 2, wherein The interposition part has an exterior material provided with a conductive material layer,
The antenna device further includes a support member that is a dielectric that holds the radiating element along the front surface or the back surface of the exterior member in a state of being separated from the conductive material layer.
The moving body according to any one of claims 1 to 4, characterized in that: The interposition part is a hollow structure in which a wire harness configured by bundling a plurality of electric wires is arranged in a hollow part,
The radiating element is disposed along the surface of the wire harness,
The feeder lines connected to the first feeding point and the second feeding point are bundled with the plurality of electric wires,
The moving body according to any one of claims 1 to 4, characterized in that: The interposition part has an interior material made of an insulating material,
The radiating element is disposed along the front surface or the back surface of the interior material,
The moving body according to any one of claims 1 to 4, characterized in that:

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