JP2008135944A - High frequency glass antenna for automobiles and window glass plate - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a high frequency glass antenna for automobiles which improves an antenna gain in a wide band. <P>SOLUTION: A first antenna element 1 and a second antenna element 2 are connected by a first connection conductor 3; the first antenna element 1, the second antenna element 2, and the first connection conductor 3 compose a U character type conductor pattern; the first antenna element 1 is connected to a power feeding unit 8 through a second connection conductor 4; a third antenna element 10 is attached to the power feeding unit 8 or the second connection conductor 4; and the third antenna element 10 is extended to a direction which departs from the first antenna element 1. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a high-frequency glass antenna for an automobile and a window suitable for receiving domestic terrestrial digital television broadcasting (470 to 770 MHz), domestic UHF band analog television broadcasting (470 to 770 MHz) or US digital television broadcasting (698 to 806 MHz). It relates to glass plates.

  Conventionally, as a high-frequency glass antenna for automobiles that receives domestic terrestrial digital television broadcasting, a substantially U-shaped antenna conductor is provided on a window glass plate, and a power feeding part is provided at one of two end portions of the antenna conductor. I was using something.

  However, in this conventional example, the configuration of the antenna conductor is simple, sufficient antenna gain cannot be obtained, there is only one resonance frequency, and it is not possible to cope with the wideband of the domestic terrestrial digital television broadcasting band, and is flat. There is a problem that it is not possible to obtain an antenna gain having the characteristics. There is no patent document corresponding to this.

  An object of the present invention is to solve the above-mentioned drawbacks of the prior art and provide a high-frequency glass antenna for automobiles that has not been conventionally known.

The present invention relates to a high-frequency glass antenna for an automobile in which an antenna conductor and a feeding portion are provided on an automotive window glass plate,
The antenna conductor comprises a first antenna element, a second antenna element, a third antenna element and a first connecting conductor;
Seen from inside or outside the car,
The first antenna element and the second antenna element are connected by a first connection conductor, and the first antenna element, the second antenna element, and the first connection conductor are U-shaped, substantially U-shaped. , J-shaped or substantially J-shaped conductor pattern,
The first antenna element is connected to the feeding portion directly or via the second connection conductor,
A third antenna element is attached to the feeding part or the second connection conductor,
The third antenna element is extended in a direction away from the first antenna element, and provides a high-frequency glass antenna for an automobile.

  In the present invention, since the third antenna element is provided, adjusting the conductor length of the third element 10 makes it easier to adjust the antenna gain in the higher frequency range than the center frequency of the desired broadcast frequency band. This facilitates flattening of the antenna gain in a desired broadcast frequency band.

  Further, when the auxiliary conductor is attached to the ground portion, the antenna gain is further improved dramatically.

  When the antenna conductor has a loop portion, since the antenna conductor has a plurality of resonance frequencies, the desired broadcast frequency band can be set to domestic terrestrial digital television broadcasting, domestic UHF without impairing the visual field and aesthetics of the window. Even in a wideband broadcast frequency band such as a band analog television broadcast or a US digital television broadcast, an antenna gain having high antenna gain and flatness can be obtained. Further, since the area occupied by the antenna conductor and the power feeding portion is small, it can contribute to a reduction in space.

  Furthermore, when a laminated glass plate is used as the window glass plate, the antenna conductor can be provided between the two glass plates constituting the laminated glass plate, so that it is suitable as a high-frequency glass antenna for automobiles for front window glass plates. ing.

  Hereinafter, the high frequency glass antenna for automobiles of the present invention will be described in detail based on preferred embodiments shown in the accompanying drawings. FIG. 1 is a plan view (inside view or outside view) of an embodiment of a high frequency glass antenna for a glass for automobiles according to the present invention.

In FIG. 1, 1 is a first antenna element, 2 is a second antenna element, 3 is a first connection conductor, 4 is a second connection conductor provided as required, and 5 is a vehicle body opening edge of a window ( In FIG. 1, the vehicle body opening edge of the upper window is shown), 6 (broken line part) is a loop forming antenna element provided if necessary, 7 (broken line part) is a ground part provided if necessary, 8 feeding unit, 9 (broken line portion) of the third antenna element auxiliary conductors 9, 12 is a window glass sheet for an automobile, 15 parasitic conductor, 19 a virtual straight line, D ₀ is the distance. In the following description, unless otherwise specified, a direction refers to a direction on the drawing. In FIG. 1, the peripheral part of the window glass plate 12 is not shown. Hereinafter, the “antenna element” is omitted and simply referred to as “element”.

  In the present invention, there are two basic modes: a case where the ground portion 7 is provided and a case where the ground portion 7 is not provided. When the earthing part 7 is not provided in the window glass plate 12, it becomes a monopole antenna, and the reception signal of the electric power feeding part 8 is sent to a receiver (not shown). On the other hand, when the earth part 7 is provided in the window glass plate 12, it becomes a bipolar antenna, and a reception signal between the power feeding part 8 and the earth part 7 is sent to the receiver. When the ground part 7 is provided, the ground part 7 is provided in the vicinity of the power feeding part 8 of the window glass plate 12. In addition, it is preferable that the shortest space | interval between the electric power feeding part 8 and the earth | ground part 7 is 2-30 mm.

  In the following description, the description of the antenna conductor and the feeding unit 8 will be a description common to the monopolar antenna and the bipolar antenna, and the description of the auxiliary conductor 9 and the ground unit 7 will be the description of only the bipolar antenna.

  As shown in FIG. 1, in the present invention, the antenna conductor and the feeding portion 8 are provided on the window glass plate 12. The antenna conductor includes a first element 1, a second element 2, a third element 10, and a first connection conductor 3.

  The first element 1 and the second element 2 are connected by a first connection conductor 3. The first element 1, the second element 2, and the first connection conductor 3 constitute a U-shaped, substantially U-shaped, J-shaped or substantially J-shaped conductor pattern.

  In the example shown in FIG. 1, the first element 1 is connected to the power feeding unit 8 via the second connection conductor 4, and such an aspect is preferable for improving the antenna gain. However, the present invention is not limited to this, and the first element 1 can be used even if it is directly connected to the power supply unit 8.

  Further, a third element 10 is attached to the second connection conductor 4. Such an aspect is preferable in terms of improving the antenna gain. However, the present invention is not limited to this, and the third element 10 can be used even if it is directly attached to the power supply unit 8, and can be used even if the third element 10 is attached to the loop forming element 6 described later. . The third element 10 is extended in a direction away from the first element 1.

  In the example shown in FIG. 1, in order to improve the antenna gain, the auxiliary conductor 9 is attached to the ground portion 7, and the auxiliary conductor 9 is extended in a direction away from the power feeding portion 7. When the antenna gain is improved by attaching the auxiliary conductor 9 to the ground portion 7 in this manner, it is preferable to provide the auxiliary conductor 9. When the auxiliary conductor 9 is attached to the ground portion 7, the shortest distance between the ground portion 7 and the auxiliary conductor 9 and the third element 10 is preferably 3 to 50 mm. When the shortest interval is 3 mm or more, the antenna gain is improved as compared with the case where the shortest interval is less than 3 mm. When this shortest interval is 50 mm or less, a space can be reduced as compared with the case where it is more than 50 mm, which is preferable. A more preferable range is 10 to 30 mm. For the same reason, when the auxiliary conductor 9 is not attached to the ground portion 7, the shortest distance between the ground portion 7 and the third element 10 is 3 to 50 mm, particularly 10 to 30 mm. Is preferred.

  In the example shown in FIG. 1, a straight line passing through the center or center of gravity of the power feeding unit 8 and the center or center of gravity of the ground unit 7 is assumed. When the virtual line 19 is referred to, the auxiliary conductor 9 is parallel or substantially parallel to the virtual line 19. The auxiliary conductor 9 is parallel or substantially parallel to the vehicle body opening edge 5 of the window. Such an embodiment is preferable because the antenna gain is improved. However, the present invention is not limited to this, and the auxiliary conductor 9 can be used even if it is not parallel or substantially parallel to the virtual straight line 19 and the auxiliary conductor 9 is not parallel or substantially parallel to the vehicle body opening edge 5 of the window.

  In the example shown in FIG. 1, the antenna conductor and the auxiliary conductor 9 are arranged on the side opposite to the vehicle body opening edge 5 side of the window that is closest to the power feeding unit 8 with the virtual straight line 19 as a boundary. Such an aspect improves the antenna gain, and such an aspect is preferable. However, the present invention is not limited to this, and the antenna conductor or the auxiliary conductor 9 can be used even if the antenna conductor or the auxiliary conductor 9 is disposed on the vehicle body opening edge 5 side of the window that is closest to the power feeding portion 8 with the virtual straight line 19 as a boundary. The auxiliary conductor 9 has a function for adjusting the impedance, and a position where the auxiliary conductor 9 is arranged is changed, and a distance between the vehicle body opening edge 5 of the window and the auxiliary conductor 9 is changed. And the impedance between the ground portion 7 can be varied.

  In the example illustrated in FIG. 1, the power feeding unit 8 and the ground unit 7 are arranged so that a virtual straight line 19 extends along the vehicle body opening edge 5 of the window closest to the power feeding unit 8. Such an embodiment is preferable because it facilitates mounting and improves the antenna gain. However, the present invention is not limited to this, and it can be used even if the power supply unit 8 and the grounding unit 7 are not arranged so that the virtual straight line 19 extends along the vehicle body opening edge 5 of the window closest to the power supply unit 8. .

  In the example shown in FIG. 1, the first element 1 and the third element 10 are arranged in parallel or substantially parallel to the virtual straight line 19. Further, the first element 1 and the third element 10 constitute a straight line. Further, the auxiliary conductor 9 is parallel or substantially parallel to the virtual straight line 19. Such an embodiment is preferable because the antenna gain is improved and the space can be reduced. However, the present invention is not limited to this, and can be used without adopting such an aspect.

  In the example shown in FIG. 1, an auxiliary conductor 9 is provided at or near the ground portion 7 farthest from the vehicle body opening edge 5 of the window closest to the ground portion 7. Such an embodiment is preferable in order to reduce the influence of the vehicle body opening edge 5 of the window on the antenna performance. However, the present invention is not limited to this, and the auxiliary conductor 9 can be used even if the auxiliary conductor 9 is not provided in the above-mentioned place or the vicinity thereof.

  FIG. 3 is a plan view (inside view or outside view) of an embodiment different from FIG. In the example shown in FIG. 3, the auxiliary conductor 9 is connected to the ground portion 7 via the auxiliary conductor connecting conductor 20, and the vehicle body opening edge 5 of the window in which the auxiliary conductor connecting conductor 20 is closest to the ground portion 7. The auxiliary conductor connecting conductor 20 is extended in a direction away from the vehicle body opening edge 5 of the window.

In the present invention, the wavelength in the air at the lowest frequency of the desired broadcast frequency band is called λ _L , the glass wavelength shortening rate is called k, λ _gL = λ _L · k, k = 0.64, When the wavelength in the air at the highest frequency of the broadcast frequency band is called λ _H and λ _gH = λ _H · k, and the auxiliary conductor 9 is not provided in the ground portion 7, the maximum length of the ground portion 7 when that _{L a,} it is preferred from the viewpoint of improving the antenna gain is _{L a = (λ gH / 8} ) ~ (λ gL / 2).
And the ground portion 7 auxiliary conductor 9 is provided, when the auxiliary conductor connection conductor 20 is not provided, the conductor length of the auxiliary conductor 9 is called a L _b, auxiliary conductors 9 are attached to the ground part 7 When the length of the ground portion 7 and the location of the ground portion 7 farthest from the location is _denoted by L _c , when L _a ≧ (L _b + L _c ), L _a = (λ _gH / 8) ˜ (Λ _gL / 2) is preferable in terms of improving the antenna gain. When L _a <(L _b + L _c ), it is preferable that (L _b + L _c ) = (λ _gH / 8) to (λ _gL / 2) from the viewpoint of improving the antenna gain.
The auxiliary conductor 9 and the auxiliary conductor connecting conductor 20 are provided in the ground portion 7, the conductor length of the auxiliary conductor connecting conductor 20 is referred to as L _d, and the auxiliary conductor connecting conductor 20 is attached to the earth portion 7. When the length between the location and the location of the ground portion 7 farthest from the location is _denoted by L _c , if L _a ≧ (L _b + L _c + L _d ), then L _a = (λ _gH / 8) ˜ (Λ _gL / 2) is preferable in terms of improving the antenna gain. Further, when L _a <(L _b + L _c + L _d ), (L _b + L _c + L _d ) = (λ _gH / 8) to (λ _gL / 2) improves the antenna gain. This is preferable.

In the present invention, when receiving the domestic terrestrial digital television broadcasting, when the ground part 7 auxiliary conductor 9 is not provided, when the maximum length of the ground portion of L _a, L _{a =} 31~204mm This is preferable in terms of improving the antenna gain. Moreover, an auxiliary conductor 9 is provided on the ground part 7, when the auxiliary conductor connection conductor 20 is not provided, the conductor length of the auxiliary conductor 9 is called a L _b, the auxiliary conductor 9 to the ground part 7 When the length between the attached portion and the place of the ground portion 7 farthest from the place is referred to as L _c , when L _a ≧ (L _b + L _c ), L _a = 31 to 204 mm. This is preferable in terms of improving the antenna gain. When L _a <(L _b + L _c ), it is preferable that (L _b + L _c ) = 31 to 204 mm from the viewpoint of improving the antenna gain.
Further, the auxiliary conductor 9 and the auxiliary conductor connecting conductor 20 are provided in the ground portion 7, the conductor length of the auxiliary conductor connecting conductor 20 is referred to as L _d, and the auxiliary conductor connecting conductor 20 is attached to the ground portion 7. When the length of the ground portion 7 and the location of the ground portion 7 farthest from the location is referred to as L _c , when L _a ≧ (L _b + L _c + L _d ), L _a = 31 to 204 mm This is preferable in terms of improving the antenna gain. Further, when L _a <(L _b + L _c + L _d ), it is preferable that (L _b + L _c + L _d ) = 31 to 204 mm from the viewpoint of improving the antenna gain.

  Here, the shape of the ground portion 7 is not particularly limited. However, as shown in FIG. 1, a rectangular shape and a substantially rectangular shape are preferable from the viewpoint of improving antenna gain for convenience in mounting. However, the present invention is not limited to this, and a square, a substantially square, a circle, a substantially circle, an ellipse, a substantially ellipse, or the like can be used.

  The maximum length of the ground part 7 will be described. When the shape of the ground portion 7 is a square or a substantially square, the maximum length of the ground portion 7 is the maximum diagonal line. When the shape of the ground portion 7 is a circle or a substantially circle, the maximum length of the ground portion 7 is a diameter. When the shape of the ground part 7 is an ellipse or a substantially ellipse, the maximum length of the ground part 7 is the long axis.

In the present invention, the conductor length of the first element 1 is (λ _gH / 4) to (λ _gL / 2), particularly 1.2 · (λ _gH / 4) to 0.8 · (λ _gL / 2) is preferable in terms of improving the antenna gain from the center frequency to the low range.

In the present invention, the sum of the conductor length of the first element 1, the conductor length of the first connection conductor 3, and the conductor length of the second element 2 is (λ _gH / 2) to λ _gL , 2 · (λ _gH / 2) to 0.8 · λ _gL is preferable in terms of improving the antenna gain.

  In the present invention, when receiving a domestic terrestrial digital television broadcast, the length of the first element is 62 to 204 mm, particularly 74 to 163 mm. This is preferable in terms of improving the antenna gain from the center frequency to the low range. The antenna gain is such that the total length of the first element 1, the first connection conductor 3 and the second element 2 is 124 to 408 mm, particularly 149 to 326 mm. It is preferable in terms of improvement.

The conductor length of the third element 10 is preferably (1/4) · λ _gL or less, and particularly preferably (1/5) · λ _gL or less in order to improve the antenna gain. The conductor length of the third element 10 mainly affects the antenna gain in the higher range than the center frequency of the desired broadcast frequency band. In this case, if the conductor length of the third element 10 is relatively short in the range of (1/4) · λ _gL or less, the antenna gain of the higher frequency out of the higher frequency than the center frequency of the desired broadcast frequency band is obtained. When the conductor length of the third element 10 is relatively long in the range of (1/4) · λ _gL or less, the lower one of the higher frequencies than the center frequency of the desired broadcast frequency band tends to be larger. The antenna gain tends to increase.

  In the present invention, when domestic terrestrial digital television broadcasting is received, it is preferable that the conductor length of the third element 10 is 102 mm or less, particularly 82 mm or less, because the antenna gain is improved.

In the example illustrated in FIG. 1, the first element 1, the first connection conductor 3, and the loop forming element 6 constitute a loop portion. However, it is not limited to this, The following aspects may be sufficient.
When at least one of the first element 1 and the loop forming element 6 is directly connected to the power supply unit 8, the first element 1, the first connection conductor 3, and the power supply unit 8 are selected. At least one of these and the loop forming element 6 constitute a loop portion.
When at least one of the first element 1 and the loop forming element 6 and the power supply unit 8 are connected via the second connection conductor 4, the first element 1 and the first connection At least one selected from the conductor 3, the second connection conductor 4, and the power feeding portion 8 and the loop forming element 6 constitute a loop portion.

  In the example shown in FIG. 1, the tip of the first element 1 on the side opposite to the first connection conductor 3 is connected to the second connection conductor 4. However, the present invention is not limited to this, and the vicinity of the tip may be connected to the second connection conductor 4. Further, when the second connection conductor 4 is not provided, even if the distal end portion of the first element 1 on the side opposite to the first connection conductor 3 or the vicinity of the distal end portion is directly connected to the power feeding portion 8. Good.

  In the example shown in FIG. 1, a power feeding portion 8 is provided on the side opposite to the first connection conductor 3 when viewed from the center of the first element 1. The loop forming element 6 is extended toward the power feeding unit 8 side in parallel or substantially in parallel with the first element 1 starting from a predetermined location of the first connection conductor 3. The loop forming element 6 bends or bends in the vicinity of the power supply unit 8 toward the power supply unit 8 side, and is connected to the front end portion or the vicinity of the front end portion of the first element 1 on the power supply unit 8 side. The point is connected to the power feeding unit 8 through the second connection conductor 4. However, the connection point may be directly connected to the power feeding unit 8.

  Although not shown, as an example different from the example shown in FIG. 1, a power feeding unit 8 is provided on the side opposite to the first connection conductor 3 when viewed from the center of the first element 1. The loop forming element 6 is extended toward the power feeding unit 8 side in parallel or substantially in parallel with the first element 1 starting from a predetermined location of the first connection conductor 3. The first element 1 and the loop forming element 6 may be joined in the vicinity of the power supply unit 8 and directly connected to the power supply unit. In addition, the present invention is not limited to this, and the first element 1 and the loop forming element 6 are merged in the vicinity of the power supply unit 8, and after being merged, connected to the power supply unit via the second connection conductor 3. May be.

In the present invention, the wavelength in the air at the center frequency of the desired broadcast frequency band is referred to as λ _c, and when λ _gc = λ _c · k, the first element 1 is an element constituting the loop portion. The average distance between the first element 1 and the loop forming element 6 is preferably 0.0065λ _gc or more from the viewpoint of improving the antenna gain. A more preferable range of this range is 0.0161λ _gc or more, and a particularly preferable range is 0.0242λ _gc or more.

The average distance between the second element 2 and the loop forming element 6 is preferably 0.0065λ _gc or more from the viewpoint of improving the antenna gain. A more preferable range of this range is 0.0161λ _gc or more, and a particularly preferable range is 0.0242λ _gc .

The distance between the first element 1 and the second element 2 is preferably 0.0565λ _{gc to} 0.170λ _gc from the viewpoint of improving the antenna gain. A more preferable range is 0.0791λ _{gc to} 0.147λ _gc .

  FIG. 3 is a plan view (inside view or outside view) of an embodiment different from the embodiment shown in FIG. In the example shown in FIG. 3, the shape of the 1st connection conductor 3 is a fan-shaped arc or a substantially fan-shaped arc. However, the present invention is not limited to this, and the first connecting conductor 3 can be used even when the shape of the first connecting conductor 3 is a semicircular arc, a substantially semicircular arc, a semielliptical arc, or a substantially semielliptical arc. In addition, a cross-shaped auxiliary element 21 is provided in the loop portion, and four tip portions of the auxiliary element 21 are connected to the loop portion in the vertical and horizontal directions. It is preferable that the intersection of the auxiliary elements 21 and the center or center of gravity of the loop portion match or substantially match.

  In the present invention, in order to improve the antenna gain, it is preferable to provide a conductor layer in part or all of the loop portion. Further, it is preferable that part or all of the conductor layer is connected to the loop portion in order to improve the antenna gain. Furthermore, this conductor layer may be integrated with at least the loop portion. The conductor layer may be a linear conductor. In this case, a plurality of the linear conductors are preferable. However, the present invention is not limited to this, and the antenna gain can be improved even with one linear conductor. The cross-shaped auxiliary element 21 is an example of this linear conductor, and is preferable in terms of securing a field of view as compared to providing a conductor layer in the entire loop portion.

  In the present invention, it is preferable to provide a parasitic conductor 15 that is spaced apart from the second element 2 by a predetermined distance and is not connected to the antenna conductor in a direct current, in order to improve the antenna gain. The parasitic conductor 15 is preferably provided in parallel or substantially parallel to the second element 2 in order to improve the antenna gain.

  In the present invention, when receiving a domestic terrestrial digital television broadcast, it is preferable that the parasitic conductor 15 has a conductor length of 55 to 165 mm in order to improve antenna gain. The distance between the second element 2 and the parasitic conductor 15 is preferably 1 to 20 mm, and particularly preferably 2 to 10 mm in order to improve the antenna gain.

  FIG. 4 is a plan view (inside view or outside view) of an embodiment different from the embodiment shown in FIG. In the example shown in FIG. 4, the ground portion 7 is disposed between the vehicle body opening edge 5 of the window and the power feeding portion 8.

  In the present invention, the window glass plate 12 may be a single glass plate or a laminated glass plate (not shown). When the window glass plate 12 is a laminated glass plate, the window glass plate 12 is made of a synthetic resin interposed between the vehicle inner glass plate, the vehicle outer glass plate, and the vehicle inner glass plate and the vehicle outer glass plate. An intermediate film is provided. The vehicle inner side glass plate and the vehicle outer side glass plate are bonded by this intermediate film, and the intermediate film functions as an adhesive layer.

  The antenna conductor and the power feeding portion 8 may be provided on the surface on the intermediate film side of the vehicle interior glass plate, and such an aspect is preferable for convenience in mounting. However, the present invention is not limited to this, and the antenna conductor and the power feeding portion 8 may be provided on the surface on the intermediate film side of the vehicle outer side glass plate. In other words, the antenna conductor and the power feeding portion 8 are provided between the vehicle inner glass plate and the vehicle outer glass plate. In this case, it is preferable for the convenience of mounting to provide a counter electrode on the surface on the vehicle inner side of the glass plate on the vehicle inner side facing the portion where the power supply unit 8 is provided. The inner conductor of a coaxial cable (not shown) connected to the receiver is usually connected to this counter electrode.

  In the present invention, at least one of the antenna conductor, the second ground conductor 4, the power feeding unit 8, the ground unit 7, and the auxiliary conductor 9 includes a phase adjustment conductor, an antenna performance adjustment conductor, or an antenna performance adjustment. A fine adjustment conductor or the like may be provided.

  In the case where the power feeding unit 8 is provided on the inner surface of the window glass plate, the inner conductor of the coaxial cable is normally connected to the power feeding unit 8. In the case where the ground portion 7 is provided on the inner surface of the window glass plate, the outer conductor of the coaxial cable is usually connected to the ground portion 7. Note that the means for connecting the coaxial cable to the power feeding unit 8 and the ground unit 7 is not limited to the means for direct connection by soldering or the like, and may be connected via a connector.

  The window glass plate 12 on which the high-frequency glass antenna for automobiles of the present invention is provided may be any one such as a front window glass plate, a rear window glass plate, a side window glass plate, and a roof window glass plate, and is particularly limited. Not. However, when a laminated glass plate is used as the window glass plate 12, a front window glass plate that is effective from the viewpoint of safety is preferable.

  The antenna conductor, the feeding portion 8, the second grounding conductor 4, the auxiliary conductor 9, and the grounding portion 7 may be formed by printing and baking a paste containing a conductive metal such as silver paste on the window glass plate 12. Good. However, it is not limited to this forming method, and a linear body or a foil-like body made of a conductive material such as copper may be formed on the window glass plate 12 with an adhesive or the like.

  In the present invention, a concealment film is formed on the surface of the window glass plate 12, and the antenna conductor, the power supply unit 8, the second connection conductor 4, the counter electrode 18, the ground conductor 9 and the ground unit 7 are formed on the concealment film. At least one selected part or the whole may be provided. Examples of the concealing film include ceramics such as a black ceramic film. In this case, when viewed from the outside of the window glass plate 12, the portion of the antenna conductor or the like provided on the concealment film is shielded by the concealment film, so that the antenna device is not seen from the outside of the vehicle. It becomes the window glass plate 12. Examples of the material of the intermediate film 16 include polyvinyl butyral.

  The present invention will be described below with reference to examples, but the present invention is not limited to these examples, and various improvements and modifications are also included in the present invention as long as the gist of the present invention is not impaired. Hereinafter, embodiments will be described in detail with reference to the drawings. A high-frequency glass antenna for an automobile as shown in FIGS. 1, 4, 5, and 8 was manufactured using a rear window glass plate of the automobile. 5 and 8 are plan views (interior view) showing the arrangement of antenna conductors and the like on the rear window glass plate 12a. The antenna conductor, the feeding point 8, the grounding part 7, and the auxiliary conductor 9 were formed by sticking copper foil on the inner side surface of the rear window glass plate 12a with an adhesive.

"Example 1 (Example)"
Measurement was performed using the high frequency glass antennas for automobiles as shown in FIGS. Here, the example shown in FIG. 5 is an example in which the automotive high-frequency glass antenna shown in FIG. 1 is provided on the rear window glass plate 12a. The first element 1 and the second element 2 were substantially parallel to the horizontal plane. The parasitic conductor 15 was not provided. The loop forming element 6, the grounding part 7, and the auxiliary conductor 9 were provided. In FIG. 5, 30 is an antenna conductor for FM broadcast band, 31 is a power feeding part, 32 is an antenna conductor for AM broadcasting band, and 33 is a power feeding part.

  Of the angles formed by the rear window glass plate 12a and the horizontal plane, the smaller angle was 25 °. The dimensions of each part are as follows. FIG. 6 shows a frequency-antenna gain characteristic diagram.

W ₁ (maximum width of the vehicle body opening edge 5 of the window) 1240 mm,
W ₂ (maximum vertical width of window opening edge 5 of window) 690 mm
Rear window glass plate 12a 130 (maximum horizontal length) x 750 (maximum vertical length) mm,
Conductor length of the first element 1 95 mm,
The conductor length of the second element 2 is 150 mm,
The conductor length of the third element 10 is 55 mm,
The distance between the second element 2 and the loop forming element 6 is 20 mm,
The conductor length of the first connecting conductor 3 is 40 mm,
The conductor length of the second connecting conductor 4 is 20 mm,
The conductor length of the auxiliary conductor 9 is 80 mm,
The conductor width of the first element 1, the conductor width of the second element 2, the conductor width of the first connection conductor 4, and the conductor width of the second connection conductor 3 are 0.7 mm.

D ₁ 400 mm,
D ₂ (the distance between the ground point 9 and the vehicle body opening edge 5 of the upper window) 10 mm,
D ₃ 30 mm,
D ₄ 135mm,
D ₅ 60mm,
L ₁ 300mm,
20 mm, the shortest distance between the third element 10 and the ground part 7
Feeding point 8 (vertical width x horizontal width) 20 x 15 mm,
Grounding point 9 (vertical width x horizontal width) 20 x 40 mm,
The shortest distance between the power supply unit 8 and the ground unit 7 is 10 mm.

"Example 2 (Example, Comparative example)"
Among the manufactured high frequency glass antennas for automobiles, those shown in FIGS. 4 and 8 were used as examples. The same automobile as in Example 1 was used. The loop forming element 6 and the ground part 7 were provided. The condition of the rear window glass plate 12a, which is different from that of Example 1, is that the FM broadcast band antenna conductor 30, the feeding part 31, the AM broadcasting band antenna conductor 32 and the feeding part 33 are not provided, and the upper shape of the defogger is different. That is.

  In FIG. 4, a device without the third element 10 was also manufactured and arranged as shown in FIG. In the example, the first element 1 and the second element 2 were substantially parallel to the horizontal plane. In the comparative example, the first element 1 was substantially parallel to the horizontal plane.

  The dimensions different from Example 1 are as follows. A characteristic diagram of frequency-antenna gain is shown in FIG. In FIG. 7, the antenna gain of the example is shown with the antenna gain of the comparative example being 0 (zero) dBi as a reference. The black point on the horizontal axis of 0 dBi is a measurement point in the comparative example, and the same applies to FIGS.

The conductor length of the first element 1 is 100 mm,
The conductor length of the second element 2 is 150 mm,
Conductor length of the third element 10 (when provided) 50 mm,
The distance between the second element 2 and the loop forming element 6 is 20 mm,
The conductor length of the first connecting conductor 3 is 40 mm,
The conductor length of the second connecting conductor 4 is 20 mm,
The conductor width of the first element 1, the conductor width of the second element 2, the conductor width of the first connection conductor 4, and the conductor width of the second connection conductor 3 are 0.7 mm.

D ₁₀ 300 mm,
D ₁₁ (the distance between the ground point 9 and the vehicle body opening edge 5 of the upper window) 10 mm,
D ₁₂ 25mm,
The shortest distance 35 mm between the third element 10 and the earthing part 7,
Feeding point 8 (vertical width × horizontal width) 10 × 10 mm,
Grounding point 9 (length x width) 10 x 105mm,
The distance between the power supply unit 8 and the ground unit 7 is 5 mm.

"Example 3 (Example)"
A high-frequency glass antenna for automobiles similar to Example 1 was produced except that the parasitic conductor 15 was provided. FIG. 9 shows a frequency-antenna gain characteristic diagram with the measured value of Example 1 as a reference (0 dB). The dimensions of each part are as follows.

D ₀ 30 mm,
5 mm between the second element 2 and the parasitic conductor 15,
The conductor length of the parasitic conductor 15 is 110 mm.

"Example 4 (Example)"
A high-frequency glass antenna for automobiles similar to Example 3 was manufactured except that a cross-shaped auxiliary element was provided in the loop portion. In FIG. 1 showing Example 1, the cross-shaped auxiliary element is not shown, but the cross-shaped auxiliary element is arranged so that the intersection of the cross-shaped auxiliary element coincides with the center of the loop portion. FIG. 10 shows a frequency-antenna gain characteristic diagram with the measured value of Example 3 as a reference (0 dB).

  INDUSTRIAL APPLICABILITY The present invention is used for an automotive glass antenna that receives terrestrial digital television broadcasts, UHF band analog television broadcasts and US digital television broadcasts, digital television broadcasts in the European Union region, or digital television broadcasts in the People's Republic of China. In addition, Japanese FM broadcast band (76-90 MHz), US FM broadcast band (88-108 MHz), TV VHF band (90-108 MHz, 170-222 MHz), 800 MHz band (810-960 MHz) for car phones, automobiles 1.5 GHz band (1.429 to 1.501 GHz) for telephones, UHF band (300 MHz to 3 GHz), GPS (Global Positioning System), GPS signal of artificial satellite 1575.42 MHz, VICS (Vehicle Information and Communication System, (Vehicle Information and Communication System: 2.5 GHz)

  Furthermore, ETC communication (Electronic Toll Collection System: non-stop automatic toll collection system, roadside wireless device transmission frequency: 5.795 GHz or 5.805 GHz, roadside wireless device reception frequency 5.835 GHz or 5.845 GHz), dedicated narrow Regional communication (DSRC: Dedicated Short Range Communication, 915 MHz band, 5.8 GHz band, 60 GHz band), microwave (1 GHz to 3 THz), millimeter wave (30 to 300 GHz), keyless entry system for automobile (300 to 450 MHz), and And SDARS (Satellite Digital Audio Radio Service (2.34 GHz, 2.6 GHz)) communication.

The top view of one Embodiment of the high frequency glass antenna for glass automobiles of this invention. The top view which shows a prior art example. The top view of embodiment different from embodiment shown in FIG. The top view of embodiment different from embodiment shown in FIG. The top view which shows the rear window glass plate 12a in which the high frequency glass antenna for motor vehicle glass cars of Example 1 is provided. The frequency-antenna gain characteristic figure in Example 1. FIG. The frequency-antenna gain characteristic figure in Example 2. FIG. The top view which shows the rear window glass plate 12a in which the high frequency glass antenna for automotive glass vehicles of Example 2 is provided. The frequency-antenna gain characteristic figure in Example 3. The frequency-antenna gain characteristic figure in Example 4.

Explanation of symbols

1: 1st element 2: 2nd element 3: 1st connection conductor 4: 2nd connection conductor 5: Car body opening edge of window 6: Loop forming element 7: Earthing part 8: Feeding part 9: Auxiliary conductor 10: Third element 12: Window glass plate 12a: Rear window glass plate

Claims (31)

In an automotive high-frequency glass antenna in which an antenna conductor and a power feeding part are provided on an automotive window glass plate,
The antenna conductor comprises a first antenna element, a second antenna element, a third antenna element and a first connecting conductor;
Seen from inside or outside the car,
The first antenna element and the second antenna element are connected by a first connection conductor, and the first antenna element, the second antenna element, and the first connection conductor are U-shaped, substantially U-shaped. , J-shaped or substantially J-shaped conductor pattern,
The first antenna element is connected to the feeding portion directly or via the second connection conductor,
A third antenna element is attached to the feeding part or the second connection conductor,
The high frequency glass antenna for automobiles, wherein the third antenna element is extended in a direction away from the first antenna element. An earth part is provided in the vicinity of the power feeding part of the window glass plate,
The high frequency glass antenna for an automobile according to claim 1, wherein a reception signal between the power feeding unit and the ground unit is sent to the receiver. If necessary, an auxiliary conductor is attached to the ground part, and the auxiliary conductor extends in a direction away from the power supply part,
When an auxiliary conductor is attached to the ground portion, the shortest distance between the ground portion and the auxiliary conductor and the third antenna element is 3 to 50 mm,
The high frequency glass antenna for an automobile according to claim 2, wherein when the auxiliary conductor is not attached to the ground portion, the shortest distance between the ground portion and the third antenna element is 3 to 50 mm. Assuming a straight line that passes through the center or center of gravity of the power supply unit and the center or center of gravity of the ground part, when referred to as a virtual straight line,
The high-frequency glass antenna for an automobile according to claim 3, wherein the antenna conductor and the auxiliary conductor are arranged on the side opposite to the vehicle body opening edge side of the window closest to the power feeding portion with the virtual straight line as a boundary. Assuming a straight line that passes through the center or center of gravity of the power supply unit and the center or center of gravity of the ground part, when referred to as a virtual straight line,
The high frequency glass antenna for an automobile according to any one of claims 2 to 4, wherein a power feeding part and a grounding part are arranged so that a virtual straight line extends along a vehicle body opening edge of a window closest to the power feeding part. . Assuming a straight line that passes through the center or center of gravity of the power supply unit and the center or center of gravity of the ground part, when referred to as a virtual straight line,
The high frequency glass antenna for an automobile according to any one of claims 2 to 5, wherein the first antenna element and the third antenna element are arranged in parallel or substantially parallel to a virtual straight line. The wavelength in the air at the lowest frequency of the desired broadcast frequency band is called λ _L , the glass wavelength shortening rate is called k, λ _gL = λ _L · k, and k = 0.64, the third antenna The high-frequency glass antenna for an automobile according to any one of claims 1 to 6, wherein the element 10 has a conductor length of (1/4) · _λgL or less.   The high frequency glass antenna for an automobile according to any one of claims 1 to 6, wherein a conductor length of the third antenna element is 102 mm or less. Assuming a straight line that passes through the center or center of gravity of the power supply unit and the center or center of gravity of the ground part, when referred to as a virtual straight line,
The high frequency glass antenna for an automobile according to claim 3, wherein the auxiliary conductor is parallel or substantially parallel to a virtual straight line.   The high-frequency glass antenna for an automobile according to claim 3 or 9, wherein the auxiliary conductor is attached at a location of the ground portion furthest from a vehicle body opening edge of the window closest to the ground portion or in the vicinity thereof. The auxiliary conductor is connected to the grounding portion via an auxiliary conductor connecting conductor;
The auxiliary conductor connecting conductor is attached at or near the location of the ground portion furthest from the vehicle body opening edge of the window closest to the ground portion, and the auxiliary conductor connecting conductor extends from the vehicle body opening edge of the window. The high-frequency glass antenna for automobiles according to claim 3, 9 or 10, which is extended in a direction away from the automobile. The ground portion is provided on the window glass plate,
The wavelength in the air at the lowest frequency of the desired broadcast frequency band is called λ _L , the glass wavelength shortening rate is called k, λ _gL = λ _L · k, k = 0.64, and the desired broadcast frequency band referred to as λ _H a wavelength in the air at the highest frequency, when the λ _{gH =} λ _H · k,
When the auxiliary conductors to ground portion is not provided, when the maximum length of the ground portion of _{L a, L a = (λ} gH / 8) a ~ (λ _gL / 2),
And auxiliary conductors are provided on the grounding section, when the auxiliary conductor connection conductor is not provided, the conductor length of the auxiliary conductors is called a L _b, and locations the auxiliary conductors is attached to a ground portion When the length of the ground part that is the farthest from the part is L _c ,
When L _a ≧ (L _b + L _c ), L _a = (λ _gH / 8) to (λ _gL / 2),
When L _a <(L _b + L _c ), (L _b + L _c ) = (λ _gH / 8) to (λ _gL / 2),
An auxiliary conductor and an auxiliary conductor connecting conductor are provided in the ground portion, the conductor length of the auxiliary conductor connecting conductor is referred to as L _d , and the location where the auxiliary conductor connecting conductor is attached to the ground portion and from the location When the length from the most distant ground part is L _c ,
When L _a ≧ (L _b + L _c + L _d ), L _a = (λ _gH / 8) to (λ _gL / 2),
When L _a <(L _b + L _c + L _d ), (L _b + L _c + L _d ) = (λ _gH / 8) to (λ _gL / 2). The high frequency glass antenna for automobiles as described. The ground portion is provided on the window glass plate,
When the auxiliary conductors to ground portion is not provided, when the maximum length of the ground portion of _{L a,} a L a = 31~204mm,
And auxiliary conductors are provided on the grounding section, when the auxiliary conductor connection conductor is not provided, the conductor length of the auxiliary conductors is called a L _b, and locations the auxiliary conductors is attached to a ground portion When the length of the ground part that is the farthest from the part is L _c ,
When L _a ≧ (L _b + L _c ), L _a = 31 to 204 mm,
When L _a <(L _b + L _c ), (L _b + L _c ) = 31 to 204 mm,
An auxiliary conductor and an auxiliary conductor connecting conductor are provided in the ground portion, the conductor length of the auxiliary conductor connecting conductor is referred to as L _d , and the location where the auxiliary conductor connecting conductor is attached to the ground portion and from the location When the length from the most distant ground part is L _c ,
When L _a ≧ (L _b + L _c + L _d ), L _a = 31 to 204 mm,
The high frequency glass antenna for an automobile according to any one of claims 1 to 11, wherein when L _a <(L _b + L _c + L _d ), (L _b + L _c + L _d ) = 31 to 204 mm. The wavelength in the air at the lowest frequency of the desired broadcast frequency band is called λ _L , the glass wavelength shortening rate is called k, λ _gL = λ _L · k, k = 0.64, and the desired broadcast frequency band referred to as λ _H a wavelength in the air at the highest frequency, when the λ _{gH =} λ _H · k,
The conductor length of the first antenna element is (λ _gH / 4) to (λ _gL / 2),
The sum of the conductor length of the first antenna element, the conductor length of the first connection conductor, and the conductor length of the second antenna element is (λ _gH / 2) to λ _gL. A high-frequency glass antenna for automobiles according to claim 1. The conductor length of the first antenna element is 62 to 204 mm,
14. The automobile according to claim 1, wherein a total length of a conductor length of the first antenna element, a conductor length of the first connection conductor, and a conductor length of the second antenna element is 124 to 408 mm. High frequency glass antenna. The antenna conductor comprises a loop forming antenna element;
At least one of the first antenna element and the loop-forming antenna element and the feeding portion are connected directly or via the second connection conductor;
When at least one of the first antenna element and the loop-forming antenna element is directly connected to the power supply unit, the first antenna element, the first connection conductor, and the power supply unit are selected. At least one and the loop forming antenna element constitute a loop part,
When at least one of the first antenna element and the loop forming antenna element is connected to the power feeding unit via the second connection conductor, the first antenna element, the first connection conductor, The high frequency glass antenna for an automobile according to any one of claims 1 to 15, wherein a loop portion is constituted by at least one selected from the second connection conductor and the power feeding portion and the loop forming antenna element. The feeding section is provided on the side opposite to the first connection conductor as seen from the center of the first antenna element;
Starting from a predetermined location of the first connection conductor, the loop-forming antenna element is extended toward the feeding portion side in parallel or substantially parallel to the first antenna element,
The loop-forming antenna element bends or bends in the vicinity of the power feeding unit toward the power feeding unit, and is connected to the front end portion or the vicinity of the front end portion of the first antenna element on the power feeding unit side, directly or the second The automotive high-frequency glass antenna according to claim 16, wherein the automotive high-frequency glass antenna is connected to the power feeding portion via a connecting conductor. When the first antenna element is directly connected to the power feeding unit, the tip of the first antenna element on the side opposite to the first connection conductor or the vicinity of the tip is connected to the power feeding unit. And
When the first antenna element is connected to the feeding portion via the second connection conductor, the tip portion of the first antenna element on the side opposite to the first connection conductor or the vicinity of the tip portion is the second. The high frequency glass antenna for motor vehicles in any one of Claims 1-17 connected to the connection conductor of this. The feeding section is provided on the side opposite to the first connection conductor as seen from the center of the first antenna element;
Starting from a predetermined location of the first connection conductor, the loop-forming antenna element is extended toward the feeding portion side in parallel or substantially parallel to the first antenna element,
The high frequency wave for automobiles according to claim 16 or 17, wherein the first antenna element and the loop forming antenna element are merged in the vicinity of the power feeding unit and connected to the power feeding unit directly or via the second connection conductor. Glass antenna. The ground portion is provided on the window glass plate,
The high-frequency glass antenna for an automobile according to any one of claims 2 to 19, wherein a shortest distance between the power feeding portion and the ground portion is 2 to 30 mm. When the wavelength in the air at the center frequency of the desired broadcast frequency band is called λ _c , the glass wavelength shortening rate is called k, k = 0.64, and λ _gc = λ _c · k,
The first antenna element is included in an element constituting the loop portion;
The high frequency glass antenna for an automobile according to any one of claims 16, 17 and 19, wherein an average interval between the first antenna element and the loop forming antenna element is 0.0065λ _gc or more. When the wavelength in the air at the center frequency of the desired broadcast frequency band is called λ _c , the glass wavelength shortening rate is called k, k = 0.64, and λ _gc = λ _c · k,
The high-frequency glass antenna for an automobile according to any one of claims 16, 17, 19 and 21, wherein an average interval between the second antenna element and the loop-forming antenna element is 0.0065λ _gc or more.   The conductor layer is provided in a part or all of the loop part, or one or a plurality of linear conductors are provided in the loop part. High frequency glass antenna for automobiles.   A cross-shaped auxiliary antenna element is provided in the loop portion, and four tip portions of the auxiliary antenna element are respectively connected to the loop portion in the upper, lower, left and right directions. A high-frequency glass antenna for automobiles according to claim 1.   The shape of the first connection conductor is a straight line, a sector arc, a substantially sector arc, a semicircular arc, a substantially semicircular arc, a semielliptical arc, or a substantially semielliptical arc. The high frequency glass antenna for automobiles according to any one of the above.   The high-frequency glass antenna for an automobile according to any one of claims 1 to 25, further comprising a parasitic conductor that is spaced apart from the second antenna element by a predetermined distance and is not DC-connected to the antenna conductor.   27. The high frequency glass antenna for an automobile according to any one of claims 1 to 26, wherein the antenna conductor functions to receive a broadcast frequency band of a digital television.   A dielectric film is formed on the surface of the window glass plate, and at least one portion selected from the antenna conductor, the loop-forming antenna element, the auxiliary conductor, and the auxiliary conductor connecting conductor on the dielectric film. Or the high frequency glass antenna for motor vehicles in any one of Claims 1-27 which provided the whole.   The high frequency glass antenna for automobiles according to any one of claims 1 to 28, wherein the frequency of the received radio wave includes a frequency existing between 470 and 770 MHz.   The high-frequency glass antenna for an automobile according to any one of claims 1 to 28, wherein the frequency of the received radio wave includes a frequency existing between 698 and 806 MHz.   The window glass board for motor vehicles provided with the antenna conductor as described in Claim 1-30 at least.

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