JP7083290B2 - Laminated glass for vehicle window glass - Google Patents

Description

The present disclosure relates to laminated glass having an antenna and used for window glass of vehicles such as vehicles.

Patent Document 1 describes that a laminated glass having an antenna and a heating wire is used for the windshield and the rear glass of a vehicle. This laminated glass has two glass plates and an adhesive intermediate layer arranged between them. Further, a heat generating layer made of a resin film coated with a heating wire is arranged at the center in the thickness direction of the intermediate layer, and an antenna is arranged on the outer surface of one of the glass plates or inside the intermediate layer. The antenna is arranged in the area where the heating wire is not provided when viewed from the normal direction of the laminated glass.

JP-A-2017-183063

In laminated glass in which the antenna is arranged in the intermediate layer, the antenna is coupled to the feeding portion by a non-contact type coupling such as capacitive coupling, and it is desired to strengthen this coupling.

In view of such a problem, the present invention relates to a laminated glass for a window glass of a vehicle in which an antenna layer having a resin film is arranged between an inner glass plate and an outer glass plate, to a feeding portion of the antenna. The purpose is to strengthen the non-contact type bond.

The laminated glass according to at least some embodiments of the present invention is a laminated glass (1) for a window glass of a vehicle, which is an inner glass plate (2) arranged inside and an outer glass arranged outside. An antenna layer having a first film (10) made of a resin and an antenna wire (11) arranged between the plate (3) and the inner glass plate and the outer glass plate and adhered to the first film. (4), an adhesive first intermediate layer (6) arranged between the inner glass plate and the antenna layers, and an adhesive second intermediate layer (6) arranged between the antenna layer and the outer glass plate. 7) and a feeding unit (9) arranged inside the inner glass plate and connected to the antenna wire so as to be able to transmit a signal, and the antenna layer includes the inner glass plate and the outer glass plate. It is characterized in that it is arranged closer to the inner glass plate side than the center between the two.

According to this configuration, the distance from the feeding portion to the antenna wire is shortened, so that the non-contact type coupling of the antenna to the feeding portion is strengthened.

The laminated glass according to at least some embodiments of the present invention is characterized in that, in the above configuration, the antenna wire is capacitively coupled to the feeding portion.

This configuration facilitates signal transduction connections between the antenna wire and the feeding section.

In any of the above configurations, the laminated glass according to at least some embodiments of the present invention is arranged between the antenna layer and the second intermediate layer, and is made of a resin as a second film (12) and the second intermediate layer. The heat-generating layer (5) having a heating wire (13) adhered to the film further has an adhesive third intermediate layer (8) arranged between the antenna layer and the heat-generating layer, and the heat-generating layer. Is characterized in that it is arranged closer to the outer glass plate side than the center between the inner glass plate and the outer glass plate.

According to this configuration, even if a force that distorts the heat generating layer due to heat generated by the heating wire acts, the second intermediate layer is compared with the case where the heat generating layer is arranged in the center between the inner glass plate and the outer glass plate. However, its distortion is suppressed by its relatively thinness and the rigidity of the outer glass plate. Further, since the heat generating layer is arranged close to the outer glass plate, it is advantageous for defrosting the frost adhering to the outer surface of the laminated glass. Further, even if a force that distorts the antenna layer by receiving the heat of the heating wire works, the first intermediate layer is thinner than the case where the antenna layer is arranged in the center between the inner glass plate and the outer glass plate. In addition, the distortion is suppressed by the rigidity of the inner glass plate.

In the laminated glass according to at least some embodiments of the present invention, in the above configuration, the antenna wire and the heating wire are orthogonal to each other in at least a part of the region seen from the normal direction of the laminated glass. It is characterized by being placed.

According to this configuration, the radio wave having the polarization in the direction orthogonal to the heating line is not interfered with by the heating line, so that it can be efficiently transmitted and received by the antenna wire orthogonal to the heating line.

In the laminated glass according to at least some embodiments of the present invention, in the above configuration, the antenna wire extends in the horizontal direction and the heating wire extends in the vertical direction in at least a part of the region. It is a feature. Here, the "horizontal direction" means the horizontal direction along the surface of the laminated glass, and the "vertical direction" means the direction orthogonal to the horizontal direction along the surface of the laminated glass.

According to this configuration, the antenna wire can transmit and / or receive the horizontally polarized wave without being interfered with by the heating wire.

The laminated glass according to at least some embodiments of the present invention is characterized in that, in the above configuration, the antenna wire transmits / receives a signal of terrestrial digital television broadcasting.

According to this configuration, the horizontally polarized terrestrial digital television broadcast signal can be transmitted and received without being interfered with by the heating line.

According to the present invention, in a laminated glass having an antenna layer, the non-contact type coupling to the feeding portion of the antenna can be strengthened.

Schematic sectional view of laminated glass according to 1st Embodiment Schematic sectional view of laminated glass according to 2nd Embodiment Schematic sectional view of laminated glass according to a third embodiment

Hereinafter, embodiments in which the present invention is applied to an automobile windshield will be described with reference to the drawings. 1 to 3 are schematic cross-sectional views in a cross section orthogonal to the lateral direction (horizontal direction along the surface of the laminated glass 1) of the laminated glass 1 according to the first to fourth embodiments, respectively.

The laminated glass 1 according to the first embodiment is arranged between the inner glass plate 2 arranged on the vehicle interior side, the outer glass plate 3 arranged on the outside of the vehicle interior, the inner glass plate 2 and the outer glass plate 3. The antenna layer 4, the heat generating layer 5 arranged between the inner glass plate 2 and the outer glass plate 3, and the first intermediate layer arranged between the inner glass plate 2 and the antenna layer 4 so as to adhere to each other. 6, the second intermediate layer 7 arranged between the heat generating layer 5 and the outer glass plate 3 so as to adhere to each other, and the antenna layer 4 and the heat generating layer 5 arranged between the two so as to adhere to each other. It has a third intermediate layer 8 and a feeding portion 9 arranged inside the inner glass plate 2.

The laminated glass 1 used for the windshield of an automobile is gently curved so that the outer surface swells. The inner surface of the inner glass plate 2 and the outer surface of the outer glass plate 3 form the inner surface and the outer surface of the laminated glass 1, respectively. The distance between the outer surface of the inner glass plate 2 and the inner surface of the outer glass plate 3 may be constant, but may change, for example, to be smaller or larger toward the upper side.

The antenna layer 4 has a first film 10 and an antenna wire 11 adhered to the first film 10. The first film 10 is a base material that supports the antenna wire 11, and is made of a resin that transmits visible light. As the resin constituting the first film 10, for example, polyethylene terephthalate, polyethylene, polymethylmethacrylate, polyvinyl chloride, polyester, polyolefin, polycarbonate, polystyrene, polypropylene, nylon and the like can be used. The antenna wire 11 is made of a conductive substance. For example, as the antenna wire 11, a metal such as copper, aluminum, tungsten, or silver can be used. The antenna layer 4 is arranged closer to the inner glass plate 2 than the center between the inner glass plate 2 and the outer glass plate 3.

The heat generating layer 5 has a second film 12 and a heating wire 13 adhered to the second film 12. The second film 12 is a base material that supports the heating wire 13, and is made of a resin that transmits visible light similar to that of the first film 10. The heating wire 13 is made of the same conductive substance as the antenna wire 11. The heat generating layer 5 is arranged closer to the outer glass plate 3 than the center between the inner glass plate 2 and the outer glass plate 3.

When viewed from the normal direction of the laminated glass 1, the antenna wire 11 and the heating wire 13 are arranged so as to overlap each other so as to be orthogonal to each other in a part of the region. For example, the antenna wire 11 extends in the horizontal direction so as to transmit and receive the signal of the horizontally polarized terrestrial digital television broadcast, and the heating wire 13 extends in the vertical direction (alignment) so as not to interfere with the reception of the horizontally polarized wave by the antenna wire 11. It extends along the surface of the glass 1 and in a direction orthogonal to the lateral direction). The antenna wire 11 and the heating wire 13 may be arranged on the entire laminated glass 1 or may be partially arranged. When viewed from the normal direction of the laminated glass 1, there may be a region where only the antenna wire 11 is arranged or a region where only the heating wire 13 is arranged.

The antenna layer 4 and the heat generating layer 5 may have the same horizontal dimensions and vertical dimensions as the inner glass plate 2 and the outer glass plate 3, respectively, as in the first embodiment shown in FIG. 1, respectively. As in the second embodiment shown in the above, the inner glass plate 2 and the outer glass plate 3 may have smaller horizontal dimensions and vertical dimensions. Further, the surfaces of the antenna layer 4 and the heating layer 5 to which the antenna wire 11 or the heating wire 13 is adhered may face the outer glass plate 3 side, respectively, as in the first embodiment shown in FIG. As in the third embodiment shown in FIG. 3, the inner glass plate 2 may be facing the side.

The antenna layer 4 and the heat generating layer 5 can be created by etching, printing, transfer, or the like, respectively. The formation of the antenna layer 4 and the heating layer 5 by etching is suitable for thinning the antenna wire 11 and the heating wire 13 in order to make the antenna wire 11 and the heating wire 13 difficult to see from the driver or the like.

The creation of the antenna layer 4 by etching will be described. First, a thin metal film used as a material for the antenna wire 11 is adhered to the first film 10 by, for example, a sticking method, a plating method, a sputtering method, a CVD method, a PVD method, a vacuum vapor deposition method, an ion plating method, or the like. .. Next, a resist layer is provided on the metal thin film, and the pattern is transferred to the resist layer by photolithography or the like. After development and washing, the metal thin film in the portion not covered by the resist layer is removed by etching. The case where the heat generating layer 5 is created by etching is the same as the case of the antenna layer 4.

The first to third intermediate layers 6, 7, and 8 are each made of an adhesive resin that transmits visible light. For example, polyvinyl butyral and ethylene vinyl acetate can be used as the first to third intermediate layers 6, 7, and 8. The first and second intermediate layers 6 and 7 are preferably thinner than the third intermediate layer 8. The thickness of the first and second intermediate layers 6 and 7 is 1 to 400 μm, preferably 1 to 200 μm, and more preferably 1 to 50 μm. The thickness of the third intermediate layer 8 is preferably 600 to 2000 μm so as to facilitate thinning by stretching. The distance between the outer surface of the inner glass plate 2 and the inner surface of the outer glass plate 3 changes so as to become smaller or larger as it goes upward, so that the first to third intermediate layers 6, 7, When 8 is wedge-shaped in cross-sectional view, the above numerical value indicates the thickness of the thickest portion.

The feeding portion 9 is arranged on the inner surface of the inner glass plate 2 and is capacitively coupled to the antenna wire 11. The antenna wire 11 capacitively coupled to the feeding unit 9 transmits and / or receives a signal in a frequency band of 100 MHz or higher. The feeding unit 9 and the antenna wire 11 may be connected so as to be able to transmit signals to each other, even if they are not capacitively coupled. For example, the feeding unit 9 may be coupled to the antenna wire 11 by a conducting wire. In this case, the feeding portion 9 may be arranged between the inner glass plate 2 and the outer glass plate 3.

A method for manufacturing the laminated glass 1 will be described. First, a laminated body in which an inner glass plate 2, a first intermediate layer 6, an antenna layer 4, a third intermediate layer 8, a heat generating layer 5, a second intermediate layer 7 and an outer glass plate 3 are laminated in this order is created. Next, the laminate is pre-bonded. Pre-adhesion is performed, for example, by placing the laminate in a rubber bag and heating it to about 70 to 110 ° C. while sucking under reduced pressure. For pre-adhesion, the laminate is heated to 45 to 65 ° C. by an oven, pressed at 0.45 to 0.55 MPa by a roll, further heated to 80 to 105 ° C. by an oven, and then 0.45 to 0.45 by a roll. It may be done by pressing again at 0.55 MPa. Next, the pre-bonded laminate is main-bonded. The main bonding is performed, for example, by heating the pre-bonded laminate to 100 to 150 ° C. by an autoclave at a pressure of 8 to 15 atm. By performing the preliminary bonding and the main bonding in this way, the inner glass plate 2 and the antenna layer 4 are bonded to each other by the first intermediate layer 6, and the antenna layer 4 and the heat generating layer 5 are bonded to each other by the third intermediate layer 8. , The heat generating layer 5 and the outer glass plate 3 are adhered to each other by the second intermediate layer. Next, the laminated glass 1 is completed by arranging the feeding portion 9 on the inner surface of the inner glass plate 2 so as to be capacitively coupled to the antenna wire 11.

The inner glass plate 2 and the outer glass plate 3 have higher rigidity than the first to third intermediate layers 6, 7, and 8 which are adhesive resins. Further, the thickness of the second intermediate layer 7 is thinner than that in the case where the heat generating layer 5 is arranged in the center between the inner glass plate 2 and the outer glass plate 3. When the heating wire 13 is energized and generates heat, the heat exerts a force that distorts the heating layer 5, but the heating layer 5 is an outer glass plate having higher rigidity than the first to third intermediate layers 6, 7, and 8. Since the second intermediate layer 7 which is arranged closer to the side of 3 and exists between the outer glass plate 3 and the outer glass plate 3 is relatively thin, distortion is suppressed. Similarly, the thickness of the first intermediate layer 6 is smaller than that in the case where the antenna layer 4 is arranged at the center between the inner glass plate 2 and the outer glass plate 3. The heat of the heating wire exerts a force that distorts the antenna layer 4. However, the antenna layer 4 is arranged closer to the inner glass plate 2 having higher rigidity than the first to third intermediate layers 6, 7, and 8, and is a first intermediate layer existing between the inner glass plate 2 and the inner glass plate 2. Since 6 is relatively thin, distortion is suppressed. The distortion of the antenna layer 4 and the heat generating layer 5 reduces the clarity of the image of the object seen by the driver when the driver of the automobile looks at the object outside the vehicle interior through the laminated glass 1, but this distortion is suppressed. Therefore, even if an object is viewed through the laminated glass 1, the object can be clearly seen.

The antenna wire 11 transmits and / or receives signals from media such as digital television, AM radio, FM radio, digital radio (DAB), mobile phones, ITS, or GPS. Since the antenna wire 11 is orthogonal to the heating wire 13 when viewed from the normal direction of the laminated glass 1, radio waves having a polarization in a direction orthogonal to the heating wire 13 are efficiently transmitted without being interfered with by the heating wire 13. It can transmit and / or receive, and the degree of freedom in the layout of the antenna wire 11 is increased.

The heating wire 13 generates heat when energized, defrosts frost adhering to the outer surface of the laminated glass 1, and prevents and removes fogging and dew condensation on the inner surface of the laminated glass 1.

Since the feeding portion 9 is arranged on the inner surface of the inner glass plate 2 and is capacitively coupled to the antenna wire 11, the feeding portion 9 is manufactured as compared with the case where the feeding portion 9 is arranged between the inner glass plate 2 and the outer glass plate 3. Is easy. Further, since the antenna layer 4 is arranged between the inner glass plate 2 and the outer glass plate 3 closer to the inner glass plate 2 side than the center, the capacitive coupling is strengthened.

Although the description of the specific embodiment is completed above, the present invention can be widely modified without being limited to the above embodiment. For example, it is not necessary to provide a heat generating layer. In this case, the first intermediate layer adheres the inner glass plate and the antenna layer to each other, and the second intermediate layer adheres the antenna layer and the outer glass plate to each other. The laminated glass according to the present invention may be applied to the rear glass or side glass of an automobile, or may be applied to a vehicle other than an automobile, for example, a window glass of a railroad vehicle, a ship, an aircraft, or the like.

1: Laminated glass 2: Inner glass plate 3: Outer glass plate 4: Antenna layer 5: Heat generation layer 6: First intermediate layer 7: Second intermediate layer 8: Third intermediate layer 9: Feeding unit 10: First film 11 : Antenna wire 12: Second film 13: Heating wire

Claims (5)

Laminated glass for vehicle window glass
The inner glass plate placed inside and
The outer glass plate placed on the outside and
An antenna layer arranged between the inner glass plate and the outer glass plate and having a first film made of a resin and an antenna wire adhered to the first film.
An adhesive first intermediate layer arranged between the inner glass plate and the antenna layers,
An adhesive second intermediate layer arranged between the antenna layer and the outer glass plate,
A second film arranged between the antenna layer and the second intermediate layer and made of a resin, and a heat generating layer having a heating wire adhered to the second film.
With the adhesive third intermediate layer arranged between the antenna layer and the heat generating layer
It has a feeding unit which is arranged inside the inner glass plate and is connected to the antenna wire so as to be able to transmit a signal.
The antenna layer is arranged closer to the inner glass plate side than the center between the inner glass plate and the outer glass plate .
The laminated glass is characterized in that the heat generating layer is arranged closer to the outer glass plate side than the center between the inner glass plate and the outer glass plate . The laminated glass according to claim 1, wherein the antenna wire is capacitively coupled to the feeding portion. The laminated glass according to claim 1 or 2 , wherein the antenna wire and the heating wire are arranged so as to be orthogonal to each other in at least a part of the region seen from the normal direction of the laminated glass. The laminated glass according to claim 3 , wherein in at least a part of the regions, the antenna wire extends in the horizontal direction and the heating wire extends in the vertical direction. The laminated glass according to claim 4 , wherein the antenna wire transmits / receives a signal of terrestrial digital television broadcasting.

Images