JP6507713B2 - Glass antenna for car - Google Patents

Description

  BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a glass antenna for a car, which is disposed on a window glass of a car.

A glass antenna for automobiles is used to receive radio waves in the FM band to UHF band such as FM broadcasting, DAB (Digital Audio Broadcasting: terrestrial digital radio broadcasting), terrestrial digital television broadcasting, or microwaves such as GPS. However, in such a glass antenna for an automobile, it may be difficult to obtain good antenna sensitivity because the size and shape of the window glass differ depending on the vehicle and the part to which it is attached.

For example, Patent Document 1 describes a glass antenna for a vehicle capable of obtaining a sufficient antenna gain even in a narrow area. Moreover, as a feed terminal of such a glass antenna, for example, a feed terminal including a catcher as described in Patent Document 2 and a connector as described in Patent Document 3 is used. A signal connection terminal unit and a ground connection terminal unit are provided. And the said signal connection terminal part is connected to the antenna side electric power feeding part of patent document 1, and the said ground connection terminal part is connected to the earth side electric power feeding part.

Furthermore, Patent Document 4 further includes a conductive strip formed of a horizontal component and a vertical component extended from the feeding point of the positive electrode, and a portion extending along and approaching one side of the feeding point of the negative electrode. By approaching the second conductive strip extended from the feeding point, the phases of the horizontal component and the vertical component of the conductive strip can be made different so that circularly polarized radio waves can be well received. An automotive glass antenna is described.

Unexamined-Japanese-Patent No. 2010-114782 JP 2008-300267 A JP 2008-035479 A JP 2003-273625 A

Conventionally, when forming a glass antenna for a vehicle using antenna feed terminals as described in Patent Documents 2 and 3, as described in Patent Document 1, by making the ground-side feed portion as large as possible A method has been used in which a good antenna sensitivity is realized by grounding the outer conductor of the coaxial cable connected to the antenna feed terminal better. However, such a method does not actively adjust the input impedance of the antenna by changing the shape of the ground side feeding portion.

The glass antenna for a vehicle described in Patent Document 4 adjusts the phase by bringing a conductor strip extended from the feeding point on the positive electrode side close to a feeding point on the negative electrode side or a second conductive strip extended from the negative electrode side. Thus, it is possible to receive circularly polarized waves well, but it is not possible to obtain a great effect when enhancing the reception performance for radio waves of a certain polarization plane.

In the case of connecting a coaxial cable to the antenna element in a glass antenna for a vehicle, the current may flow to the outside of the outer conductor of the coaxial cable to operate as a part of the antenna, and the impedance of the antenna may change. there were. Therefore, it has been common to ground the coaxial cable outer conductor in the vicinity of the antenna element to suppress the change in impedance.

However, when the terrestrial digital television broadcast glass antenna is mounted on a vehicle, it is necessary to ground the sheathed conductor of the coaxial cable at a location away from the antenna element for the convenience of design, and as a result, the antenna element and the grounding point In some cases, the distance to the antenna element is longer than the wavelength, and the impedance near the antenna element may be high.

Therefore, according to the present invention, the input impedance of a glass antenna for an automobile and the characteristic impedance of the coaxial cable connected to the glass antenna for an automobile are used even when the outer conductor of the coaxial cable is grounded at a distance from the antenna element. An object of the present invention is to provide a glass antenna for a car which can be easily fitted and which can be expected to greatly improve the sensitivity of the antenna.

The present invention relates to a glass antenna for a motor vehicle in which a coaxial cable is disposed between an antenna element and a receiver, wherein the antenna element is composed of a positive conductor and a negative conductor, and one of the positive conductor In the glass antenna for an automobile, a portion and a part of the negative electrode side conductor portion are separated at an interval g in a direction perpendicular to the glass surface and overlap each other to form an overlapping portion.

Further, according to the present invention, in the overlap portion between the positive electrode side conductor portion and the negative electrode side conductor portion, the negative electrode side conductor portion is vertically upward to the glass surface of the positive electrode side conductor portion. It is the above-mentioned glass antenna for motor vehicles.

  Furthermore, in the present invention, the positive electrode side conductor portion includes a positive electrode side feeding portion and a positive electrode side element, and the negative electrode side conductor portion includes a negative electrode side feeding portion. It is.

  Furthermore, the present invention is the above-described glass antenna for an automobile, characterized in that the negative electrode conductor portion further includes a negative electrode element extended from the negative electrode power supply portion.

  Alternatively, the present invention forms an overlap portion between the positive electrode side conductor portion and the negative electrode side conductor portion by separating a part of the positive electrode side element and a part of the negative electrode side element at an overlap distance g. The above-mentioned glass antenna for cars characterized by being.

  Alternatively, according to the present invention, the antenna element further includes a feed terminal, the positive electrode conductor further includes a positive electrode metal fitting for the feed terminal, and the negative electrode conductor further includes the feed terminal. The positive electrode side conductor portion and the negative electrode side conductor portion are provided with a negative electrode bracket, and the positive electrode bracket or the negative electrode bracket is separated from the negative electrode side feeding portion or the positive electrode side feeding portion by an overlap distance g. The above-mentioned glass antenna for an automobile, characterized in that an overlap portion of the above is formed.

Further, according to the present invention, when the antenna element is connected to the coaxial cable, an overlapping portion between the positive electrode side conductor portion and the negative electrode side conductor portion is between the connection point with the cable and the positive electrode side element. It is the above-mentioned glass antenna for motor vehicles characterized by having been inserted.

The glass antenna according to the present invention has an overlap portion in which a part of the positive electrode side conductor part and a part of the negative electrode side conductor part constituting the antenna element are separated and overlapped in the direction perpendicular to the glass surface. . Hereinafter, this spaced interval is referred to as "overlap interval g". The overlapping portion forms a conductance in the equivalent circuit. Therefore, the conductance can be adjusted by adjusting the overlap distance g and the area (length d × width e) of the overlap portion.

  And, according to the present invention, there is provided the aforementioned glass antenna for an automobile, wherein the overlap distance g is 0.5 mm to 1.5 mm.

Further, the present invention, the area of the overlapping portion of the positive electrode side conductor and the negative electrode side conductor is a above glass antenna for an automobile, which is a 10 mm ² to 300 mm ^2.

  Further, the present invention is the above-mentioned glass antenna for a car, characterized in that it is a glass antenna for receiving terrestrial digital television broadcast.

According to the present invention, the input impedance of the antenna can be largely adjusted by adjusting the overlap distance g and the area (length d × width e) of the overlap portion. It was easy to match with the characteristic impedance of the coaxial cable to be connected, and a great improvement in antenna sensitivity was achieved.

The figure (b) which looked at the glass antenna for motor vehicles of Embodiment 1 of this invention from the vehicle inner side, and the vertical direction sectional view (a) in center line h. The figure (b) which looked at the glass antenna for motor vehicles of Embodiment 2 of this invention from the vehicle inner side, and the vertical direction sectional view (a) in center line h. The figure (b) which looked at the glass antenna for motor vehicles of Embodiment 3 of this invention from the vehicle inner side, and the vertical direction sectional view (a) in center line h. Figures showing the structure of the catcher and connector of the feeding terminal used in the first to third embodiments of the present invention (a) a view of the catcher and the connector viewed from the lower side, (b) a view of the catcher and the connector viewed from the upper side (C) Side view of catcher and connector. The equivalent circuit schematic of the glass antenna for motor vehicles of this invention. The view from the inside of a car when the antenna according to the third embodiment of the present invention is provided on the windshield of a car The view from the inside of a car when the antenna according to the third embodiment of the present invention is provided on the rear glass of a car The view from the inside of a car when the antenna according to the third embodiment of the present invention is provided on the side glass of a car The top view of the glass antenna for motor vehicles of the reference example 1 of this invention which performed simulation. The top view of the glass antenna for motor vehicles of the reference example 2 of this invention which performed simulation. The top view of the glass antenna for motor vehicles of the reference example 3 of this invention which performed simulation. The figure which showed the simulation result regarding the glass antenna for motor vehicles of the reference example 1 of this invention. The figure which showed the simulation result of the conditions 1 in connection with the glass antenna for motor vehicles of the reference example 2 of this invention. The figure which showed the simulation result of the conditions 2 regarding the glass antenna for motor vehicles of the reference example 2 of this invention. The figure which showed the simulation result regarding the glass antenna for motor vehicles of the reference example 3 of this invention.

1 to 3 show a view from the inside of a car glass antenna according to various embodiments of the present invention. In the following description, when referring to the direction perpendicular to the glass surface, the direction from the glass surface on which the glass antenna for an automobile of the present invention is disposed to the inside of the vehicle, that is, the arrow z in FIGS. Direction. In addition, when referring to "upper", "lower", "left" and "right", unless otherwise specified, they are on the upper side with respect to a certain reference, lower side, and left side in the drawing, respectively. When you are in

First Embodiment
<A configuration in which the negative electrode side conductor portion and the positive electrode side conductor portion are provided separately on the window glass: a negative electrode side power feeding portion which is a part of the negative electrode side conductor portion and a positive electrode side metal fitting which is a part of the positive electrode side conductor portion Form to overlap by providing separately on the window glass>
The glass antenna of the present invention can also be configured as in the first embodiment shown in FIG. FIG. 1B is a view of the glass antenna according to the first embodiment as viewed from the inside of a car, and the glass antenna according to the present embodiment is formed on the inner surface side of a window glass. Further, FIG. 1 (a) is a view showing a longitudinal cross section along the center line f of the feed terminal 2 in FIG. 1 (b).

In the glass antenna of the present embodiment, the following configuration is employed as the positive electrode side conductor portion and the negative electrode side conductor portion that constitute the antenna element 1. That is, the positive electrode side feeding portion 13 and the positive electrode side element 11 are provided on the window glass 6 as a positive electrode side conductor portion, and the positive electrode side element 11 is further extended, for example, from the positive electrode side feeding portion 13 A positive electrode side element second wire which is branched from the element first wire 111 and the positive electrode side element first wire 111 and is separated and parallelly drawn on the same glass surface as the positive electrode side element first wire 111 And 112.

In addition, as the negative electrode side conductor portion, the positive electrode side power feeding portion 13 and the negative electrode side power feeding portion 14 provided, for example, in the longitudinal direction so as to be separated on the window glass, and the negative electrode side element 12 are provided. Further, for example, the negative electrode side element 12 is drawn from the negative electrode side element first filament 121 drawn from the negative electrode side feeding part 14 and the same glass as the negative electrode side element first filament 121 is drawn similarly from the negative electrode side feeding part 14 It is comprised from the negative electrode side element 2nd filament 122 extended | separated and parallelly separated on a surface.

In the glass antenna of the present embodiment, the feeding terminal 2 is used to connect a coaxial cable 3 for connecting a receiver (not shown) and the antenna element 1 of the glass antenna of the present embodiment. The structure of the feed terminal 2 will be described later. In the glass antenna of the present embodiment, the distance between the antenna element 1 and the ground point of the outer conductor of the coaxial cable 3 is 20 cm, and is usually 25 cm or less. If the distance is longer than this distance, the high frequency current flowing to the outer conductor of the coaxial cable may resonate, which is not preferable.

The feed terminal 2 used in the glass antenna according to the present embodiment includes a catcher 21 connected in advance to the inner surface of the window glass 6 as shown in FIG. 1A and a connector 25 connected to the catcher 21. One end of the coaxial cable 3 is connected to the connector 25 and the other end is connected to the receiver. When the power supply terminal 2 is connected to the window glass, the positive electrode bracket 22 and the negative electrode bracket 23 are disposed so as to face the window glass 6 at an overlap distance g apart from each other.

The positive electrode bracket 22 includes a positive electrode side contact 221 and a positive electrode bracket housing portion 222 connected to the positive electrode side contact 221 and disposed on the back surface of the catcher 21. The positive electrode side contact is a portion connected to the positive electrode side power feeding portion 13 by solder and a conductive adhesive. In addition, the positive electrode bracket housing portion 222 is provided with an inclined portion 222a at the connection point with the positive electrode side contact 221, and when the power supply terminal 2 is attached to the window glass 6, a part of the positive electrode bracket housing portion 222 and the window glass 6 is configured to have a gap g.

The negative electrode bracket 23 includes a negative electrode side contact 231 and a negative electrode bracket housing portion 232 connected to the negative electrode side contact 231 and disposed on the back surface of the catcher 21. The negative electrode side contact 231 is a portion connected to the negative electrode side power supply unit 13 by solder and a conductive adhesive. In addition, the negative electrode bracket housing portion 232 is provided with an inclined portion 232a at the connection point with the negative electrode side contact, and when the power supply terminal 2 is attached to the window glass, a part of the negative electrode bracket housing portion 232 and the window glass 6 Are configured to allow an interval g.

The positive electrode bracket 22 constitutes a part of the positive electrode side conductor portion, and the negative electrode bracket 23 constitutes a part of the negative electrode side conductor portion. That is, in the glass antenna of the present embodiment, the positive electrode side conductor portion is composed of the positive electrode side power feeding portion 13, the positive electrode side element 11, and the positive electrode bracket 22 and the negative electrode side conductor portion is the negative electrode side power feeding portion 14 and the negative electrode It is comprised from the side element 12 and the metal fitting 23 for negative electrodes.

In the glass antenna of this embodiment, the negative electrode side feed portion first portion 141 for connecting the negative electrode side feed portion 14 to the negative electrode side contact 231 and the positive electrode side feed portion from the negative electrode side feed portion first portion 141 It is comprised from the negative electrode side electric power feeding part 2nd part 142 formed so that it may extend in the direction of 13. FIG. In the first embodiment, the widths of the negative electrode side feeding portion first portion 141 and the negative electrode side feeding portion second portion 142 are the same, but the width of the negative electrode side feeding portion second portion 142 is the negative electrode side feeding portion It can be changed regardless of the width of the first part 141.

[Configuration of overlap portion]
Furthermore, the positive electrode bracket housing portion 222 is formed to extend in the direction from the positive electrode side feed portion 13 to the negative electrode side feed portion 14. Then, a portion on the lower end side of the positive electrode bracket housing portion 222 and a portion on the upper end side of the negative electrode side feeding portion second portion 142 have a width e, a length d, and an overlap distance g. An overlap portion with the negative electrode side conductor portion is formed. As described above, the negative electrode side power supply unit second portion is provided to overlap with the positive electrode bracket housing portion 222 at an interval in the upper direction. In FIG. 1 (b), the positive electrode side power feeding portion 13 and the negative electrode side power feeding portion 14 are shown by oblique lines, and the positive electrode metal fitting 22 and the negative electrode metal fitting 23 are shown by dotted lines. In the glass antenna according to this embodiment, the width e, the length d, and the overlap distance g are 6 mm, 15 mm, and 1 mm, respectively, and the area of the overlap portion (length d × width e) is 90 mm ² . is there.

In the glass antenna of the present invention, the antenna element 1 formed on the window glass 6 and the coaxial line 3 are often connected via the feeding terminal 2 as described above. As in the glass antenna according to the present embodiment, the positive electrode bracket housing portion 222 which is a part of the positive electrode side bracket 22 of the power supply terminal 2 is separated from the negative electrode side conductor portion to overlap as a positive electrode side conductor portion. Therefore, there is no need to provide a special structure to provide an overlap portion between the positive electrode side conductor portion and the negative electrode side body portion, and the structure of the glass antenna of the present invention can be simplified.

[Description of operation of antenna of this embodiment]
In this embodiment, since the overlap portion between the positive electrode side conductor portion and the negative electrode side conductor portion is formed in this manner, a circuit as shown in the equivalent circuit diagram as shown in FIG. 5 is formed.
5, the impedance represented by Z _1, a glass antenna, the input impedance of the case without the overlap portion between the positive electrode side conductor and the negative electrode side conductor as a glass antenna of the embodiment of the present invention R ₁ is a radiation resistance that indicates the consumption of radio waves radiated into space, L ₁ and C ₁ are the inductance and conductance of the antenna, respectively, and Z ₁ is represented by the following equation: Can.

The antenna element 1 such as a glass antenna of the present embodiment is, if provided with an overlap portion between the positive electrode side conductor portion and the negative electrode side conductor, the overlapping portions form a conductance C _2. Then, by providing such a point, so that the impedance Z ₂ is provided in parallel with the impedance Z _1. Impedance Z ₂ is represented by the conductance C ₂ as the following equation.

Since the glass antenna of this embodiment is thus a parallel circuit of Z ₁ and Z ₂ , the input impedance Z _i will be expressed as the following equation.

Glass antenna of the present embodiment is thus overlap distance g of the overlap portion between the positive electrode side conductor size and the negative electrode side conductor of Z _2, and the area of the overlap portion (d × e) Since the input impedance of the glass antenna of this embodiment can be made close to the characteristic impedance of the coaxial cable to which the glass antenna of this embodiment is connected, the transmission loss can be reduced. The antenna sensitivity can be improved.

  In the glass antenna according to the present embodiment, the overlap distance g is preferably 0.5 to 1.5 mm, and more preferably 0.7 to 1.3 mm. If the overlap distance g is narrowed, the electric capacity can be increased and the impedance can be reduced, but the manufacturing of the terminal structure tends to be difficult.

In the glass antenna of the present embodiment, the area of the overlap portion (d × e) is dependent on the impedance of the antenna to be matched, is preferably 10 to 300 mm ^2, more preferably from 30 to 150 mm ² . When the area of the overlap portion is increased, the electric capacity is increased, and the impedance can be reduced.

In the equivalent circuit of FIG. 5, as Z _2, but shows information about only conductance C _2, not only the conductance C _2, additional elements by providing the overlapping portion between the positive electrode side conductor portion and the negative electrode side conductor In addition, not only the conductance C ₂ but also the radiation resistance and the inductance are added because the shape of the feeding portion is changed. Thus, addition of radiation resistance and inductance also contributes to the improvement of the antenna sensitivity of the glass antenna of the present embodiment.

Second Embodiment
<The embodiment in which the negative electrode side metal fitting which is a part of the negative electrode side conductor part and the positive electrode side electric supply part which is a part of the positive electrode side conductor part are provided separately on the window glass to overlap
The glass antenna of the present invention can also be configured as in the second embodiment shown in FIG. FIG. 2B is a view of the glass antenna according to the second embodiment as viewed from the inside of the vehicle, and the glass antenna according to the present embodiment is formed on the inner surface side of the window glass. Further, FIG. 2 (a) is a view showing a vertical cross section along the center line f of the feed terminal 2 in FIG. 2 (b).

Like the glass antenna of the first embodiment, the glass antenna of the present embodiment uses the feeding terminal 2 to connect the coaxial cable 3 for connecting between the receiver and the antenna element of the glass antenna of the present embodiment. ing.

In the glass antenna according to the present embodiment, the positive conductor and the negative conductor are positioned such that a portion of the positive conductor is located above the portion of the negative conductor in the direction perpendicular to the glass surface. The second embodiment differs from the first embodiment in that the second embodiment has an overlap portion with the second embodiment.

That is, in the glass antenna according to the first embodiment, the negative electrode side feeding portion 14 is connected to the negative electrode side feeding portion first portion 141 connected to the negative electrode side contact 231 of the feeding terminal 2 and the negative electrode side feeding portion first portion 141 In the glass antenna according to the present embodiment, the positive electrode side feed portion 13 is a feed terminal, although the negative electrode side feed portion second portion 142 is extended in the direction of the positive electrode side feed portion 13. From the lower side of the positive electrode side feed portion first portion 131 in the direction of the negative electrode side feed portion 14 connected to the positive electrode side feed portion first portion 131 to which the positive electrode side contact of 2 is connected and the positive electrode side feed portion first portion 131 It is comprised from the positive electrode side electric power feeding part 2nd part 132 extended | stretched by length j.

And in the glass antenna of Embodiment 1, the positive electrode side metal fitting housing part 222 which comprises the electric power feeding terminal 2 is extended in the direction of the negative electrode side metal fitting housing part 232, and overlaps with the negative electrode side electric power feeding part 2nd part 132. In the glass antenna according to the present embodiment, the negative electrode side bracket housing portion 232 constituting the feed terminal 2 is in the direction of the positive electrode side bracket housing portion 222, although the overlap portion is formed to overlap and be separated by the distance g. , And the overlap portion is formed by the positive electrode side feed portion second portion 131 with the width e, the length d, and the overlap distance g, and the overlap between the positive electrode side conductor portion and the negative electrode side conductor portion It constitutes a part. As described above, in the glass antenna according to the present embodiment, the positive electrode side feeding portion second portion 131 is separated from the negative electrode side metal fitting housing portion 232 by the overlapping distance g and used to overlap. Most of the power supply terminals 2 have a length of the negative electrode side housing portion 232 longer than a length of the positive electrode side housing portion 222. Therefore, in order to form the overlap portion between the positive electrode side conductor portion and the negative electrode side conductor portion. When using it, it is desirable in many cases to have a configuration like the glass antenna of the present embodiment.

Further, one end of the positive electrode side element first filament 111 constituting the positive electrode side element 11 is connected to the positive electrode side feeding portion first portion 131.

In the other parts, the configuration of the glass antenna of the present embodiment and the configuration of the glass antenna of the first embodiment are the same.

In the glass antenna of the present embodiment, the width of the positive electrode side feeding portion second portion 132 is narrower than the lateral width of the positive electrode side feeding portion first portion 131 constituting the positive electrode side feeding portion 13. In addition, the positive electrode side feed portion second portion 132 is connected to the positive electrode side feed portion first portion 131 such that the right side thereof is connected to the right side of the positive electrode side feed portion second portion 131.

[Configuration of overlap portion]
In general, changing the size of the positive electrode bracket 22 of the feeding terminal and the size of the negative electrode bracket 23 is difficult because it greatly affects the performance of the feeding terminal. Therefore, by forming an overlap portion so that a part of the negative electrode bracket 23 and a part of the positive electrode side feeding portion 13 are separated and overlapped at an overlap distance g, the positive electrode side conductor portion and the negative electrode side conductor portion The width, length, and position of the positive electrode feeding portion second portion 132 constituting the positive electrode feeding portion 13 are adjusted to adjust the size of the overlapping portion. Preferably, the input impedance in the desired frequency band of the glass antenna according to the present embodiment is adjusted to match the characteristic impedance of the coaxial line 3 to be connected. In FIG. 2 (b), the positive electrode side feeding portion 13 and the negative electrode side feeding portion 14 are shown by oblique lines, and the positive electrode bracket 22 and the negative electrode bracket 23 are shown by dotted lines. In the glass antenna according to this embodiment, the width e, the length d, and the overlap distance g are 3 mm, 15 mm and 1 mm, respectively, and the area of the overlap portion (length d × width e) is 45 mm ² is there.

[Operational Characteristics of Glass Antenna of This Embodiment]
The description of the operation of the overlapping portion between the positive electrode side conductor portion and the negative electrode side conductor portion in the present embodiment is the same as that of the first embodiment, and thus the description thereof is omitted here.

Embodiment 3
<A configuration in which the negative electrode side metal fitting which is a part of the negative electrode side conductor part and the positive electrode side electric supply part which is a part of the positive electrode side conductor part are provided separately on the window glass and overlapped. And the positive electrode side element is provided with an overlapping portion between the positive electrode side conductor portion and the negative electrode side conductor portion>
The glass antenna of the present invention can also be configured as in Embodiment 3 shown in FIG. FIG. 3B is a view of the glass antenna according to the third embodiment as viewed from the inside of the vehicle, and the glass antenna according to the present embodiment is formed on the inner surface side of the window glass. FIG. 3A is a view showing a vertical cross section along the center line f of the feed terminal 2 in FIG. 3B.

Like the glass antenna of the second embodiment, the glass antenna of the present embodiment uses the feeding terminal 2 to connect the coaxial cable 3 for connecting the receiver and the glass antenna of the present embodiment. Then, as in FIG. 2B, the power supply terminal 2 is shown by a dotted line also in FIG. 3B showing the present embodiment.

In the glass antenna according to the present embodiment, the positive electrode side element first filament 111 is an end portion connected to the positive electrode side power feeding portion second portion 132 in an end portion on the negative electrode side power feeding portion 14 side. The second embodiment is different from the second glass antenna 1 and the other points are the same.

[Configuration of overlap portion]
By adopting such a configuration, the glass antenna of the present embodiment allows the positive electrode side conductor portion and the negative electrode side conductor portion to be between the positive electrode side element first filament 111 and the coaxial line 3 connected to the receiver. And the overlapping part of the two is sandwiched. In this embodiment, by adopting such a configuration, the glass of Embodiment 2 is adjusted by changing and adjusting the width e and the length d of the overlapping portion between the positive electrode side conductor portion and the negative electrode side conductor portion. Since the input impedance in the desired frequency band of the glass antenna of the present embodiment becomes easier to change than the antenna 1, it becomes easy to match the characteristic impedance of the coaxial line 3. In the glass antenna according to this embodiment, the width e, the length d, and the overlap distance g are 3 mm, 15 mm and 1 mm, respectively, and the area of the overlap portion (length d × width e) is 45 mm ² is there.

[Operational Characteristics of Glass Antenna of This Embodiment]
The description of the operation of the overlap portion between the positive electrode side conductor portion and the negative electrode side conductor portion in the present embodiment is basically the same as that of the first and second embodiments, and therefore is omitted here.

However, in the glass antenna according to the present embodiment, the positive electrode side element first filament 111 is a positive electrode side conductor portion between the positive electrode side element first filament 111 and the core of the coaxial wire 3 connected to the receiver. Since the configuration is such that a part and a part of the negative electrode side conductor part are separated and overlapped by the overlap distance g, the overlap part is more than the glass antenna 1 of the second embodiment. Greatly affected by changes in length, width and spacing.

Therefore, in the glass antenna of the present embodiment, the adjustment of the input impedance of the glass antenna 1 is easier to perform than the antenna of the second embodiment.

<Method of producing glass antenna of the present invention>
Among the antenna elements 1 of the glass antenna according to the present invention, the positive electrode side element 11, the negative electrode element 12, the positive electrode side feeding portion 13 and the negative electrode side feeding portion 14 generally have the same general conductivity as forming the defogger of the rear glass. Ceramic paste can be used and printed in the same way as the defogger and can be baked by a furnace.

With regard to the overlap between the positive electrode side conductor portion and the negative electrode side conductor portion, the direction perpendicular to the glass surface of either the positive electrode side feed portion or the negative electrode side feed portion is over the lower side. A hard conductive plate such as a copper plate or an aluminum plate is bent or an insulating spacer is inserted so as to be separated by a wrap distance g, or a conductive ceramic paste is applied along the spacer, or copper foil Or a feed terminal as described later.

Furthermore, when forming the overlap part of a positive electrode side conductor part and a negative electrode side conductor part by the feed terminal 2, the feed terminal 2 generally uses a commercially available thing. Therefore, the overlap distance g between the positive electrode side contact 221 of the positive electrode bracket 22 of the feed terminal 2 and the positive electrode side bracket housing portion 222 and the distance between the negative electrode side contact 231 of the negative electrode bracket 23 and the negative electrode side bracket housing portion 232 The overlap distance g of is constant and can not be changed.

Therefore, for example, when using the feeding terminal 2 in the glass antenna of the present embodiment and using the positive electrode bracket housing portion 222 or the negative electrode bracket housing portion 232 of the feeding terminal 2 as a portion constituting the overlapping portion, The thickness of the positive electrode side feed portion 13 and the negative electrode side feed portion 14 respectively connected to the positive electrode side contact 221 and the negative electrode side contact 231 allows an overlap of the overlap portion between the positive electrode side conductor portion and the negative electrode side conductor portion. The lap interval g can be adjusted. Here, a metal plate is generally used as the positive electrode bracket 22 and the negative electrode bracket 23, and, for example, brass or a copper alloy is used, and tin plating is applied to the surface so that the solder can easily get on.

<Connection of the antenna of the present invention to the receiver>
Moreover, Embodiment 1-3 is a glass antenna provided with the positive electrode side electric power feeding part 13 and the negative electrode side electric power feeding part 14 on a window glass. In the case of such a glass antenna, the core wire and the outer conductor of the coaxial cable 3 drawn from a receiver (not shown) are connected to the positive electrode side feed portion 13 and the negative electrode side feed portion 14 directly or through the feed terminal 2. .

<Mounting position of the antenna of the present invention to the window glass>
The glass antenna of the present invention is usually mounted at a location not noticeable from the occupants of automotive window glass. For example, the feeding portion of the glass antenna according to the present invention is provided near the upper side of the windshield as shown in FIG. 6, the upper margin of the defogger 7 of the rear glass as shown in FIG. Make it

<Feeding terminal used in the antenna of the present invention>
The structure of the feed terminal 2 used in the first to third embodiments is shown in FIG. FIG. 4 shows (a) the feed terminal 2 as viewed from below, (b) the feed terminal 2 as viewed from above, and (c) the feed terminal 2 as viewed from the side. And in each figure of (a)-(c), the catcher 21 is drawn above and the connector 25 is drawn below.

The catcher 21 is composed of a box-shaped housing 24 which is open at the upper side for inserting the connector 25 and fixing it at a predetermined position, a positive electrode bracket 22 and a negative electrode bracket 23.

The positive electrode bracket 22 includes a positive electrode side contact 221 connected to the positive electrode side power feeding portion 13 provided on the window glass, and a positive electrode bracket housing portion 222 disposed in contact with the lower surface of the housing 24. . And when the catcher 21 is arrange | positioned on a window glass by providing the inclination part 222a between the positive electrode side metal fitting housing parts 222 and a positive electrode side contact, as shown in FIG.4 (c), it is the surface of a window glass And the housing 24 are spaced upward.

The negative electrode side metal fitting 23 is also the same as the positive electrode side metal fitting 22, and is disposed in contact with the negative side contact 231 connected to the negative electrode side feeding portion 14 provided on the window glass and the lower surface of the housing 24 And a negative electrode bracket housing portion 232. The negative electrode bracket housing portion 232 is provided between the surface of the window glass and the housing 24 when the catcher 21 is disposed on the window glass by providing the inclined portion 232 a with the negative electrode side contact 231. Space is provided in the direction.

The positive electrode side metal fitting housing portion 222 has a pin shape, penetrates the lower surface of the housing 24, and as shown in FIG. 4B, the positive electrode catcher side engaging portion 223 along the center line f in the front-rear direction of the housing. Is provided. Further, the negative electrode side metal fitting housing portion 232 is provided with a negative electrode catcher side engaging portion 233 along the inner wall of the side surface of the housing 24 penetrating the lower surface of the housing 24.

The connector 25 has a box-like shape matching the opening of the upper side of the housing 24. As shown in FIG. 4A, when the connector 25 is inserted into the catcher 21, the positive electrode catcher side of the catcher 21 The positive electrode connector side engaging portion 251 for inserting the engaging portion 223 and connecting with the core wire side of the coaxial cable 3 and inserting the connector 25 into the catcher 21 as shown in FIGS. 4 (a) and 4 (b) Then, a negative electrode connector side engaging portion 252 connected to the outer conductor side of the coaxial cable 3 in contact with the negative electrode catcher portion engaging portion 233 provided on the inner side surface of the housing 24 of the catcher 22 is provided. ing.

Although the connector 25 is connected to the coaxial cable 3, the core of the coaxial cable 3 is connected to the positive electrode connector side engaging portion 251 in the inside thereof, and the outer conductor is the negative electrode connector side engaging portion It is connected with 252.

The positive electrode connector side engaging portion 251 is a cylindrical conductor, and when the pin-like positive electrode catcher side engaging portion 223 is inserted, the positive electrode connector side engaging portion 251 is brought into contact and conduction can be obtained.

The connector side engaging portion 252 for a negative electrode is a plate-like conductor provided on the outer side surface of the connector 25, and by being in contact with the negative side catcher side engaging portion 233, conduction can be obtained.

The glass antenna of the present example is the glass antenna of Embodiment 3 of FIG.

The glass antenna of this embodiment uses the feeding terminal 2 to connect the coaxial cable 3 for connecting the receiver and the antenna element 1 of the glass antenna of this embodiment.

The window glass 6 includes the positive electrode side feeding portion 13, the negative electrode side feeding portion 14, the positive electrode side element 11 extending from the positive electrode side feeding portion 13, and the negative electrode side element 12 extending from the negative electrode side feeding portion 14. ing.

The positive electrode side feeding portion 13 is connected to the positive electrode side feeding portion first portion 131 connected to the positive electrode side contact 221 of the feeding terminal 2 and the positive electrode side feeding portion first portion 131 and extends in the direction of the negative electrode side feeding portion 14 And the positive electrode side feeding part second part 132. The right side of the positive electrode side feeding portion second portion 132 is connected to coincide with the right side of the positive electrode side feeding portion first portion 131.

The positive electrode side element 11 is composed of a positive electrode side element first filament 111 and a positive electrode side element second filament 112. The positive electrode side element first filament 111 is connected at one end thereof to the end of the positive electrode side feeding portion second portion 132 away from the positive electrode side feeding portion first portion and extends in the direction away from the positive electrode side feeding portion 13 It is done. Then, the positive electrode side element second wire 112 is connected to the middle of the positive electrode side element first wire 111, and is drawn so as to be parallel to the positive electrode side element first wire 111 in the plane direction of the window glass ing.

The negative electrode side element 12 is comprised from the negative electrode side element 1st filament 121 and the negative electrode side element 2nd filament 122. As shown in FIG. One end of the negative electrode-side element first filament 121 is connected to the negative electrode-side power supply unit 14, and is drawn in the direction away from the negative electrode-side power supply unit 14. Further, the negative electrode side element second wire 122 is connected to the negative electrode side power feeding portion 14 and is extended so as to be parallel to the negative electrode side element first wire 121.

The positive electrode side contact 221 of the positive electrode bracket 22 of the power supply terminal 2 and the negative electrode side contact 231 of the negative electrode bracket 23 are connected to the positive electrode side feed portion 13 and the negative electrode side feed portion 14 by soldering, respectively.

The core wire and the outer conductor of the coaxial cable 3 are connected to the positive electrode side feeding portion 13 and the negative electrode side feeding portion 14 through the positive electrode side metal fitting 22 and the negative electrode side metal fitting 23, respectively.

The positive electrode side metal fitting 22 is composed of a positive electrode side contact 221 and a positive electrode bracket housing portion 222, and is provided with an inclined portion 222a between the positive electrode side contact 221 and the positive electrode bracket housing portion 222. A negative electrode side contact 231 and a negative electrode bracket housing portion 232 are provided, and an inclined portion 232 a is provided between the negative electrode side contact 231 and the negative electrode bracket housing portion 232. When the power supply terminal 2 is attached to the window glass by the inclined portions 222a and 232a, a space is provided upward between the surface of the window glass, the positive electrode bracket housing portion 222, and the negative electrode side housing portion 232. become.

The negative electrode bracket housing portion 232 extends in the direction of the positive electrode bracket housing portion 222, and the positive electrode side feed portion second portion 132 is extended in the direction of the negative electrode side feed portion 14 so that the negative electrode bracket housing A portion of the portion 232 and a portion of the positive electrode side feed portion second portion 132 are separated at an overlap distance g and overlap each other to form an overlap portion.

Although the negative electrode bracket housing portion 232 is narrowed with respect to the width of the bottom surface of the housing 24, a part thereof is approximately the same width as the bottom surface of the housing 24. This is because a fastener for fixing the negative electrode bracket 23 to the housing 24 is formed.

The feed terminal 2 is attached such that its center line f coincides with the center line in the width direction of the positive electrode side feed portion first portion 131 and the negative electrode side feed portion 14.

Below, the dimension of each component of the glass antenna of a present Example is described.
Positive electrode side feeding part first part 131 = width 12 mm × length 12 mm
Positive electrode side feeding part second part 132 = width 6 mm × length 26 mm
Negative electrode side feeding part 14 = width 12 mm × length 12 mm
A distance of 5 mm between the lower side of the positive electrode side feed portion second portion 132 and the upper side of the negative electrode side feed portion 14
Positive side element first filament 111 = 125 mm
Positive electrode side element second filament 112 = 130 mm (dimension of location parallel to positive electrode side element first filament 111 = 120 mm)
Distance between positive electrode side element first filament 111 and positive electrode side element second filament 112 = 10 mm
Connection point of positive electrode side element second wire 112 to positive electrode side element first wire 111 = 120 mm from the tip of positive electrode side element first wire negative electrode side element first wire 121 = 40 mm
Negative element side second filament 122 = 50 mm
Distance of negative electrode side element first filament 121 and negative electrode side element second filament 122 = 10 mm
Distance between positive electrode side element second filament 112 and negative electrode side first element first filament 121 = 5 mm
The length d of the portion where the positive electrode side feed portion second portion 132 and the negative electrode bracket housing portion 232 are separated at an overlap distance g and overlap and overlap is d = 15 mm
Width e of the portion where the positive electrode side feed portion second portion 132 and the negative electrode bracket housing portion 232 are separated at an overlap distance g, overlap and overlap 3 mm
Overlap distance g = 1 mm of the portion where the positive electrode side feed portion second portion 132 and the negative electrode bracket housing portion 232 are separated at an overlap distance g and overlap and overlap
In addition, the width of each filament is 0.7 mm.

Thus, the glass antenna according to the present embodiment covers not only the positive electrode side element 11 and the negative electrode side element 12 but also a part of the positive electrode side feeding portion second portion 132 and a part of the negative electrode bracket housing portion 232 It is connected to the glass antenna 1 of this embodiment between 470 MHz and 770 MHz, which is the frequency band of terrestrial digital broadcasting, by adjusting the length and width of the overlapping and overlapping portions separated by the lap interval g. The input impedance of the glass antenna 1 of the present embodiment can be adjusted to match the characteristic impedance of the coaxial cable having a characteristic impedance of 50 Ω, and a good antenna sensitivity can be obtained in the frequency band of terrestrial digital broadcasting.

  In the reference example shown below, the size of the positive electrode side feeding portion second portion is variously changed in the antenna shape of the embodiment using simulation, and the positive electrode side feeding portion second portion 132 and the negative electrode metal fitting 23 The graph shows how the input impedance of the glass antenna changes as the width and length of the overlapping portion between them change. From the following reference example, it can be understood that the width and length of the overlapping portion are optimum for matching with the characteristic impedance of the coaxial cable 3.

Reference Example 1
Reference Example 1 is based on simulation. The glass antenna of the reference example 1 has the configuration shown in FIG. 9, and the configuration is the same as that of the antenna of the embodiment except for the lengths of the positive electrode side feeding portion second portion 132 and the positive electrode side element first filament 111.・ It is a structure. Further, in the embodiment, the positive electrode side contact 221 and the negative electrode side contact 231 are connected to the positive electrode side feed portion first portion 131 and the negative electrode side feed portion 14, but this embodiment is a simulation. The positive electrode fitting 22 and the negative electrode fitting 23 are in line contact with the positive electrode side feeding portion first portion 131 and the negative electrode side feeding portion 14 to provide a positive electrode side contact point 224 and a negative electrode side contact point 234.

In the simulation of this reference example, from the position where the right side of the positive electrode side feeding portion second portion 132 coincides with the right side of the positive electrode side feeding portion first portion 131, the width of the positive electrode side feeding portion second portion 132 is left as it is The change of the input impedance in the frequency band of digital terrestrial broadcasting when moved to

The width of the positive electrode side feed portion second portion 132 is fixed to 1 mm, and the length of the positive electrode side element first filament 111 is extended by the amount of movement of the positive electrode side feed portion second portion 132 to the left.

The conditions of the simulation of this reference example are as follows.
Method of simulation: Assuming that a conductive film is formed of copper on a finite element method glass plate Properties of the assumed glass plate: relative permittivity: ε = 7.2, dielectric loss tangent: tan Δ = 0.005
Physical property of copper: Electric conductivity: 5.8 × 10 7 S / m
The antenna is placed near the center of the glass plate.

The result of the input impedance of the glass antenna of the present example obtained by the simulation of the present reference example is shown in FIG.

In FIG. 12, the vertical axis indicates the input impedance at the calculated frequency of the glass antenna 1 of the present embodiment, and the horizontal axis indicates the right side of the positive electrode side feeding portion second portion 132, the positive electrode side feeding portion first When it agrees with the right side of the part 131 (point a), it is assumed that it is moved to 10 mm to the left with 0 mm. The solid line indicates the change in input impedance at 600 MHz, the dotted line indicates 700 MHz, and the alternate long and short dash line indicates 500 MHz.

As can be seen from FIG. 12, a change of about 20 Ω can be obtained by moving the positive electrode side feeding portion second part to a position of 0 mm to 10 mm at each frequency. Since the input impedance can be largely changed as described above, it becomes easy to obtain good antenna sensitivity.

Reference Example 2
Reference Example 2 is also based on simulation. The glass antenna 1 of the reference example 2 is of the configuration shown in FIG. 10, and this configuration is also the same as the reference example 1, and the lengths of the positive electrode side feeding portion second portion 132 and the positive electrode side element first filament 111 Except for the dimensions and configuration of the antenna of the embodiment. Further, the conditions of the simulation are the same as in the first reference example.

In the present embodiment, the width of the positive electrode side feeding portion second portion 132 is initially 1 mm, and the length is constant,
Condition 1: In the state (a) in which the right side of the positive electrode side feeding portion second portion 132 matches the right side of the positive electrode side feeding portion first portion 131, the width of the positive electrode side feeding portion second portion 132 is expanded to the left If:
Condition 2: The positive electrode is fixed to the left and right in a state in which the center line in the longitudinal direction of the positive electrode side feed part second part 132 is fixed at the center line in the longitudinal direction of the positive electrode side feed part first part 131 When the width of the side feed part second part 132 is increased:
And I checked.

Among the results of the input impedance of the glass antenna of this embodiment obtained by the simulation of this embodiment, condition 1 is shown in FIG. 13 and condition 2 is shown in FIG.

In FIG. 13 showing the result of condition 1, the vertical axis represents the input impedance at the calculated frequency of the glass antenna under condition 1 of the present embodiment, and the horizontal axis represents the width of the positive electrode side feeding portion second portion 132. It shows. The solid line indicates the change of the input impedance at 600 MHz, the dotted line indicates the 700 MHz, and the alternate long and short dash line indicates the 500 MHz.

In the case of Condition 1, the width of the feed terminal 2 is 6 mm, and the center line f in the longitudinal direction of the feed terminal 2 and the center line of the positive electrode side feed portion first portion overlap each other. Therefore, when the width of the positive electrode side feeding portion second portion is larger than 3 mm, an overlapping portion is formed with the negative electrode bracket housing portion 232. Further, according to FIG. 13, the overlapping width of the overlapping portion is 6 mm or more, that is, 9 mm or more in FIG. 13, and the negative electrode side housing portion 232 overlaps the positive electrode side feeding portion second portion 132 in the width direction. Then, it can be seen that the input impedance does not change much. From here, the overlap portion where the negative electrode bracket housing portion 232 and the positive electrode side power supply portion second portion are separated and overlapped at the overlap distance g is not less than when the widths thereof coincide with each other. It can be seen that even if the width of is broadened, the change of the input impedance can not be obtained so large by merely widening the width.

When it is desired to further lower the input impedance of the glass antenna of the present invention in such a state, the width of the overlap portion is changed, or the overlap distance g is changed, instead of increasing the width. It is better to let them respond.

In FIG. 14 showing the result of condition 2, the view is the same as FIG. Also in FIG. 14, when the width of the positive electrode side feeding portion second portion 132 is 6 mm or more, which is the same as the width of the negative electrode bracket housing portion 232, the value of the input impedance does not change significantly.

From the results of Condition 1 and Condition 2, the width of the portion where the positive electrode side feeding portion second portion 132 and the negative electrode bracket housing portion 232 are separated and overlapped at an overlapping distance g is the positive electrode side feeding portion If the width is increased to a point where the width of the second portion 132 and the negative electrode bracket housing portion 232 matches the larger one, a large change can not be obtained as the input impedance even if the width is further expanded.

Therefore, when it is intended to obtain good antenna sensitivity by actually changing the input impedance, the positive electrode side feed portion second portion 132 and the negative electrode bracket housing portion 232 are separated at an overlap distance g, overlap and overlap. It is more efficient to change the length direction while adjusting the width of the portion in advance to the width of the positive electrode side feeding portion second portion 132 or the thicker one of the negative electrode bracket housing portion 232 in advance.

In condition 1, as can be seen from FIG. 13, when the width of the positive electrode side feeding part second part 132 is 6 mm, the input impedance is 500 MHz, 600 MHz, 700 MHz most closest to the characteristic impedance 50 Ω of the coaxial cable. Become.

In condition 2, as can be seen from FIG. 14, when the width of the positive electrode side feeding part second part 132 is 6 mm, the input impedance is 500 MHz, 600 MHz, 700 MHz most closest to the characteristic impedance 50 Ω of the coaxial cable. .

Reference Example 3
Reference Example 3 is also based on simulation. The glass antenna 1 of the reference example 3 is of the configuration shown in FIG. 11, and this configuration is the same size and configuration as the reference examples 1 and 3, and the conditions of the simulation are also the same. The difference is that the length of the second portion 132 is constant while the length is changed. In Reference Example 3, since the length of the positive electrode side feeding portion second portion 132 is merely changed, the length of the positive electrode side element first filament 111 is constant.

  In this reference example, the width of the positive electrode side feeding portion second portion 132 is fixed to 12 mm, and the length is changed to 10 mm to 25 mm. When the length of the positive electrode side feed portion second portion 132 is larger than 11 mm, the positive electrode side feed portion second portion 132 and the negative electrode bracket housing portion 232 are separated at an overlap distance g and overlap each other to overlap. Form

The result of the input impedance of the glass antenna of this embodiment obtained by the simulation of this embodiment is shown in FIG. In FIG. 15, the vertical axis indicates the input impedance at the calculated frequency of the glass antenna 1 of the present embodiment, and the horizontal axis indicates the length of the positive electrode side feeding portion second portion 132. The solid line indicates the change of the input impedance at 600 MHz, the dotted line indicates the 700 MHz, and the alternate long and short dash line indicates the 500 MHz.

As can be seen from FIG. 15, the input impedance of the antenna of this embodiment decreases as the length of the positive electrode side feeding portion second portion 132 increases, that is, as the length d of the overlap portion increases. It can be understood that

In the glass antenna 1 of the present embodiment, when the length of the positive electrode side feeding portion second portion 132 is about 20 mm, that is, the length d of the overlapping portion is about 9 mm, the glass antenna 1 of the present embodiment is A value close to the characteristic impedance of 50 Ω of the coaxial cable connected to the glass antenna of the present embodiment is obtained when the input impedance value of is 600 MHz, 700 MHz, or 500 MHz, and good antenna sensitivity can be obtained.

DESCRIPTION OF SYMBOLS 1 antenna element 11 positive electrode side element 111 positive electrode side element 1st filament 112 positive electrode side element 2nd filament 12 negative electrode side element 121 negative electrode side element 1st filament 122 negative electrode side element 2nd filament 13 positive electrode side feeding part 131 positive electrode Side feed portion first portion 132 Positive side feed portion Second portion 14 Negative side feed portion 141 Negative side feed portion first portion 142 Negative side feed portion second portion 2 Feeding terminal 21 Catcher 22 Bracket for positive electrode 221 Positive side contact 222 Positive electrode Hardware housing part 222a Inclination part 223 Catcher side engaging part for positive electrode 224 Contact point on positive side 23 Metal fitting for negative electrode 231 Negative side contact 232 Metal fitting housing part for negative electrode 232a Inclined part 233 Catcher side engaging part for negative electrode 234 Negative side contact point 24 housing 25 connector 251 positive electrode connector side engaging portion 2 Engagement 2 negative connector side engaging portion 3 coaxial cable 6 windowpane 61 black border 7 defogger 71 bus bar 72 hot wire

Claims (8)

In a glass antenna for a motor vehicle, in which a coaxial cable (3) is disposed between the antenna element (1) and the receiver,
The antenna element (1) is composed of a positive conductor and a negative conductor.
A part of the positive electrode side conductor part and a part of the negative electrode side conductor part are separated from each other at an overlap distance g in a direction perpendicular to the glass surface and overlap to form an overlap part;
The positive electrode side conductor portion includes a positive electrode side power feeding portion (13) and a positive electrode side element (11).
The said negative electrode side conductor part is equipped with the negative electrode side electric power feeding part (14),
The antenna element (1) further comprises a feed terminal (2),
The positive electrode side conductor portion further includes a positive electrode bracket (22) of the feeding terminal (2),
The negative electrode side conductor portion further includes a negative electrode bracket (23) of the feeding terminal (2),
The positive electrode bracket (22) is separated from the negative electrode side feeding portion (14) by an overlap distance g, or
The negative electrode metal fitting (23) is separated from the positive electrode side power supply part (13) by an overlap distance g.
An overlap portion of the positive electrode side conductor portion and the negative electrode side conductor portion is formed. In a glass antenna for a motor vehicle, in which a coaxial cable (3) is disposed between the antenna element (1) and the receiver,
The antenna element (1) is composed of a positive conductor and a negative conductor.
A part of the positive electrode side conductor part and a part of the negative electrode side conductor part are separated from each other at an overlap distance g in a direction perpendicular to the glass surface and overlap to form an overlap part;
The positive electrode side conductor portion includes a positive electrode side power feeding portion (13) and a positive electrode side element (11).
The said negative electrode side conductor part is equipped with the negative electrode side electric power feeding part (14),
The antenna element (1) further comprises a feed terminal (2),
The positive electrode side conductor portion further includes a positive electrode bracket (22) of the feeding terminal (2),
The negative electrode side conductor portion further includes a negative electrode bracket (23) of the feeding terminal (2),
The positive electrode bracket (22) is separated from the negative electrode side feeding portion (14) by an overlap distance g, or
The negative electrode metal fitting (23) is separated from the positive electrode side power supply part (13) by an overlap distance g.
Forming an overlap portion between the positive side conductor portion and the negative side conductor portion;
When the antenna element (1) is connected to the coaxial cable (3), the positive electrode side conductor portion and the negative electrode side between the connection point with the coaxial cable (3) and the positive electrode side element (11) An automotive glass antenna characterized in that an overlapping portion with a conductor portion is inserted. In the overlap portion between the positive electrode side conductor portion and the negative electrode side conductor portion, the negative electrode side conductor portion is located on the upper side of the glass surface of the positive electrode side conductor portion in the vertical direction. Automotive glass antenna as described. The glass antenna for an automobile according to claim 1 or 2, wherein the negative electrode side conductor portion further includes a negative electrode side element (12) which is extended from the negative electrode side feeding portion (14). When the antenna element (1) is connected to the coaxial cable (3), the positive electrode side conductor portion and the negative electrode side between the connection point with the coaxial cable (3) and the positive electrode side element (11) The glass antenna for an automobile according to claim 1, wherein an overlapping portion with the conductor portion is inserted.   The said overlap space | interval g is 0.5 mm-1.5 mm, The glass antenna for motor vehicles in any one of Claims 1-5 characterized by the above-mentioned. The area of the overlapping portion of the positive electrode side conductor and the negative electrode side conductor is glass antenna for an automobile according to claim 1, characterized in that a 10 mm ² to 300 mm ^2.   It is a glass antenna for terrestrial digital television broadcast reception, The glass antenna for motor vehicles in any one of Claims 1-7 characterized by the above-mentioned.

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