JPS62193304A - Glass antenna - Google Patents

Abstract

PURPOSE:To suppress the reduction of antenna capacity by dividing a heat ray-reflective transparent conductive film having no bus bars into >=4 faces with slits among them. CONSTITUTION:At least one face of a heat ray-reflective transparent conductive film 2 is provided with at least one bus bar 5 to constitute a film-shaped antenna element 6. Heat ray-reflective transparent conductive films 2 constituting the other faces which are not provided with the bus bar 5 are divided into at least >=4 faces with slits 4 among them. That is, heat ray-reflective transparent conductive films 2 which are not provided with the bus bar 5 are provided with transverse slits 4 with respect to divide a conventional pattern, where heat ray-reflective transparent conductive films 2 which are not provided with the bus bar 5 are arranged around the heat ray-reflective transparent conductive film 2 which is provided with one bus bar 5 and constitutes the film-shaped antenna element 6 with one face, into six faces different in size.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Def] The present invention relates to a glass antenna, and particularly to a glass antenna formed by providing a heat ray reflective transparent conductive film on a glass plate surface.

[Conventional technology] Recently, there is a tendency for various communication devices such as TVs and car phones to be attacked by #IS in automobiles, and this is part of making these devices exhibit the desired characteristics. As a result, it has become essential to equip antennas with excellent gain.

In addition to various rod antennas, the antennas used in such cases include those made by printing silver paste in the desired pattern on the window glass of a car and baking it to form a linear antenna element, or Glass antennas that actively utilize the window glass surface, such as antenna elements formed by disposing conductive metal thin wires on the window glass surface, have also become widely available.

Among these various antennas, there is a noticeable tendency for the antenna pattern to gradually become more complex due to the relationship with antenna performance, etc. regarding the glass antennas listed in L, which are formed using the window glass surface of automatic 11. As the pattern becomes more complex, the antenna element becomes more visible and obstructs the view of the window glass, causing a sense of clutter from an aesthetic point of view. This has led to various inconveniences.
To solve these problems that occur when antennas for in-vehicle communication equipment are constructed using glass antennas, transparent conductive films are provided in various desired patterns on the surface of the glass plates that make up the window glass. A glass antenna has already been proposed that utilizes the glass antenna as a film-like antenna element, which does not obstruct the field of view and also eliminates the appearance of clutter.

As described above, as a conventional example of a glass antenna in which a film antenna element is formed using a transparent conductive film, a transparent conductive film 22 is formed on a part of a glass plate 21 through an insulating zone 23 as shown in FIG. Provided with this transparent conductive II! 222 bus/
<-25 is attached to form one patterned antenna element) 26, or as a modification thereof, a membrane antenna>k is placed on both sides of the element 26 and capacitively coupled via the slit 24. There is one in which a transparent conductive film 22 is arranged without a bus bar 25.

In addition, as shown in FIG. 8, in order to reduce the heating and cooling load on the window glass surface, a heat-reflecting transparent conductive film 22 is disposed on the entire surface of the glass plate 21, and the heat-reflecting transparent conductive film 22 A membrane antenna element 26 is formed by separating a part of the membrane 22 from the other part through a slit 24 and attaching a bus bar 25 thereto, or as a modification thereof, the pattern shown in FIG. Some have already been proposed.

[Problems to be Solved by the Invention] However, in the case of the glass antenna shown in FIG. 6 or FIG. There was a problem in that it was not possible to close the function to do so. In this regard, in the case of the glass antenna shown in Fig. 8 or 9,
Added cooling/heating load reduction function to the window glass surface! 1, but the heat ray reflective transparent conductive film constituting the membrane antenna element and the adjacent heat ray reflective transparent conductive film without a bus bar are capacitively coupled, etc. I learned that there is an inconvenience in that they interfere with each other and significantly degrade the antenna performance of glass antennas.

The purpose of the present invention is to solve the problems encountered when attempting to use a window glass with a cooling/heating load reduction function by forming a heat ray reflective transparent conductive film as a glass antenna provided with a membrane antenna element. In view of the problem described in E, the negative effect on the film antenna element due to the presence of the heat ray reflective transparent conductive film without a bus bar provided around the 8-ray reflective transparent conductive film constituting the film antenna element is minimized. ,
An object of the present invention is to provide a glass antenna that can obtain the desired antenna performance.

[Means for Solving the Problems] In order to achieve the above object, the present invention is configured as follows.

That is, the present invention provides a heat ray reflective transparent conductive film divided into a plurality of surfaces with slits interposed on the glass plate surface, and among these divided heat ray reflective transparent conductive films,
In a glass antenna formed by attaching at least one bus bar to at least one surface to form a membrane antenna element, the heat ray reflective transparent conductive film constituting the other surface to which no bus bar is attached is , the configuration E is divided into four or more surfaces by intervening slits.
It has the characteristics of

In addition, when implementing the present invention, the width of the slit to be interposed to divide the heat ray reflective transparent conductive film is 10 mm.
The following is desirable.

[Function] According to the present invention, the heat-reflecting transparent conductive film that is not used as a film antenna element is divided into four or more planes through slits, so it can be used as a film antenna element. Even if the induced voltage caused by the nvj reflective transparent film conductive film is capacitively coupled with the heat ray reflective transparent conductive film that does not have a bus bar, the loss can be kept low. It is possible to obtain an antenna performance equivalent to that of a conventional glass antenna (see Fig. 6), which is made by removing only the membrane antenna bar made up of the antenna and the bus bar.

Furthermore, although there are slits in the heat-reflective transparent conductive film provided on the glass plate surface,
Since it covers almost the entire surface of the glass plate, it has the function of reducing heating and cooling loads and can be used as window glass with excellent heat insulation properties.

[Example] The present invention will be described in detail below based on one drawing.

A glass plate used as window glass for appropriate parts of a car, such as a windshield, side glass, roof glass, etc., is subjected to heating and cooling loads over almost the entire surface, except for an insulating zone 3 of an appropriate width formed at the periphery. A heat ray reflective transparent conductive film 2 having a light-reducing function is divided into a plurality of surfaces with slits 4 interposed therebetween.

At least one surface of these divided heat ray reflective transparent IJJ conductive films 2 is connected to at least one busper 5.
is attached to constitute the membrane antenna element 6.

On the other hand, the heat ray reflective transparent conductive film 2 constituting the other surface to which the bus bar 5 is not attached is divided into at least four surfaces E by interposing a slit 4.

1 to 5 show specific examples of patterns of glass antennas formed in this manner.

That is, FIG. 1 shows a heat ray reflective transparent conductive film 2 having one bus bar 5 and having no bus bar 5 around a heat ray reflective transparent conductive film 2 that constitutes a film antenna element 6 on one surface. Regarding the conventional pattern shown in FIG. 8 in which a transparent conductive film 2 is arranged, horizontal slits 4 are made in the heat-reflecting transparent conductive film 2 without a bus bar 5, thereby dividing it into six large and small surfaces. FIG. 2 shows an example in which the screen is similarly divided into 10 surfaces, and FIG. 3 shows an example in which the screen is divided into 9 surfaces.

In addition, FIG. 4 shows that the shape of the heat-reflecting transparent conductive film 2, which accommodates one bus bar 5 and constitutes the film antenna element 6 on one surface, is formed into an inverted triangle. The heat ray reflective transparent conductive film 2 without the bus bar 5 located therein shows an example in which it is divided into a total of 12 surfaces by providing slits 4 in the horizontal and vertical directions. Figure 5 shows
A heat-reflective transparent conductive film 2 has one busbar 5 and has a substantially rectangular shape and constitutes a film antenna element 6. The heat ray reflective transparent conductive film 2 shown in FIG.

In addition, the specific shape and thickness of the desert antenna element 6,
Or heat ray reflective transparent conductive film 2 without busper 5
The specific shape of the dividing pattern, its size, number, etc. are not limited to the illustrated example shown in . By attaching at least one bus bar 5 to at least one surface of the transparent conductive film 2,
A heat-reflective transparent conductive film 2, which forms the vague antenna element 6 and is located around the film antenna element 6 and constitutes the other surface to which the bus bar 5 is not attached, is provided with a slit 4 interposed therebetween. Any pattern may be used as long as it is formed by a pattern divided into four or more planes. In unexploded 151, glass plate 1
The heat ray reflective transparent conductive film 2 provided on the substrate is, for example, a transparent tin oxide conductive film, a transparent hardened indium film, or a C
r, Ti.

It can be formed from a transparent metal conductive film such as Ag, ^u, AI, Cn, Ni, etc. The heat ray reflective transparent conductive film 2 having such a composition can be formed using an appropriate film forming method such as a vacuum evaporation method, a sputtering method, a CVD method, a spray method, a CLC method, or a printing method. Depending on the case, it can also be formed by pasting a heat ray reflective transparent heavy ring film.

In addition, when forming such a heat-reflecting transparent conductor 122 on a glass plate 1 having an intermediate plate structure such as tempered glass, the glass surface located on either one of the inside and outside of the mold chamber, preferably on the inside of the vehicle interior. is formed.

When the glass plate l is laminated glass, it is formed on either one of the mating surfaces or on either one of the inside and outside of the mold chamber, preferably on the glass surface of l (located on the indoor side).

In the present invention, the bus bar 5 constituting the membrane antenna element 6 is made of a conductive paste made by mixing and suspending a conductive metal powder, a low melting point glass lift, a vehicle, and other desired components. It can be formed by printing on one edge of the conductive film 2 and firing it.

In addition, the code|symbol 7 in a figure shows a feeder line.

Since the present invention is configured in this way, the heat ray reflective transparent conductive film 2 forming the film antenna element 6,
Even if the heat ray reflective transparent conductive film 2 which does not have a bus bar 5 is capacitively coupled with the adjacent heat ray reflective transparent conductive film 2 which does not have a bus bar 5 through the slit 4, the heat ray reflective transparent conductive film 2 which does not have a bus bar 5 is connected to the slit. 4 into at least four planes, the loss of induced voltage generated in the membrane antenna element 6 can be suppressed to a low level. It is possible to obtain antenna performance equivalent to that of an antenna.

In addition, by forming the slit 4 to a narrow width of 10 mm or less, it is aesthetically uncomplicated, provides excellent light shielding properties to reduce the cooling and heating load, and has heat ray reflective properties. If the presence of the transparent conductive film 2 is seen from the inside of the vehicle, it leads to low radiation and can also function as a window glass with excellent heat insulation properties.

Among the glass antennas according to the present invention, the antenna performance of the pattern shown in FIG. 3 was compared with the antenna performance of the conventional glass antennas of the patterns shown in FIGS. 6, 7258, and 9, and the results are shown in Table 1. The actual measured values shown were obtained.

In this case, the actual value obtained from the glass antenna of the antenna putter shown in Fig. 6, which is completely unaffected by the heat-reflecting transparent conductive film without bus bars, is used as the standard, and when this is taken as O, the numerical value is The antenna performance of each antenna pattern is shown by increase or decrease.

Note that the setting conditions for actually measuring the antenna performance are as follows.

-6 Width of slit 4: 5 mm - Width of insulation zone 3: 15 mm - Resistance between points of transparent conductor 1 and 2: 20 Ω (±20z) The results are as shown in Table 1, and according to this, Among the conventional glass antennas, the glass antenna according to the invention has a pattern shown in FIG.
It is found that an antenna performance approximately equal to that of the pattern shown in FIG. 6 can be obtained. In other words, it is clear that the adverse effects of the heat ray reflective transparent conductive film 2 without the bus bar 5 are reduced.

On the other hand, according to Table 1, it is found that the antenna performance of the glass antennas of the conventional patterns shown in FIGS. 8 and 9 is significantly lower than that of the one shown in FIG.

Even with such comparative values, the existence of the slit 4 in the glass antenna according to the present invention greatly improves the antenna performance! , - You can see that it is something that is done.

[Effects of the Invention] As described above, according to the present invention, a membrane antenna element
Adjacent to the heat ray reflective transparent conductive film that constitutes /<
By installing a heat-reflecting transparent conductive film without spurs on the glass plate surface, this glass plate has a function to reduce heating and cooling loads with excellent light blocking and heat insulation properties! Along with being able to j.

/- By dividing the heat ray reflective transparent conductive film without spars into four or more planes through slits, it is possible to suppress the deterioration of antenna performance, making it suitable for automatic Ichikawa glass antennas. can be used.

[Brief explanation of drawings]

1 to 5 are front views illustrating patterns of a glass antenna according to the present invention, and FIGS. 6 to 9 are front views illustrating patterns of a conventional glass antenna. 1-...Glass plate, 2...8-line reflective transparent conductive film, 3...Insulating zone. 4th: Slit, 5th: Fist bus bar. 6th place: Membrane antenna element, 711: Feeder line.

Claims (1)

[Claims] 1. A heat ray reflective transparent conductive film divided into a plurality of planes with a slit interposed is provided on the glass plate surface, and at least one of these divided heat ray reflective transparent conductive films is provided. In a glass antenna formed by attaching at least one bus bar to one surface to form a membrane antenna element,
A glass antenna characterized in that the heat ray reflective transparent conductive film constituting the other surface to which the bus bar is not attached is divided into four or more surfaces by interposing slits. 2. The glass antenna according to claim 1, wherein the width of the slit interposed when dividing the heat ray reflective transparent conductive film is 10 mm or less.