JPS61277437A - Heat-ray reflecting resin glass - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a heat ray reflective resin glass, and more particularly to a heat ray reflective resin glass in which the adhesive force between a plate-shaped resin glass and a film substrate is strengthened.

The heat-reflecting resin glass of the present invention has strong adhesive strength between the plate-shaped resin glass and the film substrate, and can be used as heat-reflecting window glass for automobiles.

[Prior Art] Conventionally, heat ray reflective resin glass has been produced in which a heat ray reflective film (consisting of a film base and a heat ray reflective film formed on the back surface of the film base) is integrally fused to the surface of a plate-shaped resin glass. Are known.

This was adopted in place of inorganic glass for the purpose of reducing weight, facilitating processing, or making the shape curved.

However, the above-mentioned conventional heat ray reflective resin glass has a drawback that the adhesive force between the plate-shaped resin glass and the film base is weak.

This is because the heat ray reflective film disposed between the plate-shaped resin glass and the film substrate is difficult to adhere to the plate-shaped resin glass.

[Problems to be Solved by the Invention] The present invention has been devised with the intention of eliminating the above-mentioned drawbacks, and is a heat ray reflective material that firmly adheres a plate-shaped resin glass and a film substrate and has sufficient strength. It provides resin glass.

[Means and effects for solving the problems] The present invention makes the heat ray reflective film have a mesh shape or a slit shape, so that the plate resin glass and the film base are brought into direct contact at multiple locations. It is a heat ray reflective resin glass.

That is, the present invention comprises: a plate-shaped resin glass; a film substrate adhered to the surface of the plate-shaped resin glass; and a film substrate formed on the back surface of the film substrate and disposed between the plate-shaped resin glass and the film substrate. A heat ray reflective resin glass having a heat ray reflective film, wherein the film base is adhered to the surface of the plate-shaped resin glass by bringing the film base into direct contact with the surface of the plate-shaped resin glass. This heat ray reflective resin glass is characterized in that there are a mixture of areas where the heat rays are exposed and areas where the heat rays are reflected indirectly through the heat ray reflective film.

Here, the shape of the plate-shaped resin glass matches the shape of the heat ray reflective resin glass that is the final product, and this can be molded by extrusion molding, casting, or other methods.

In addition, the materials for sheet resin glass include PC (polycarbonate), MMA (methyl methacrylate), M
Non-transparent colored materials such as AS (methyl acrylate-styrene), PA (polyamide), PS (polystyrene), and AS (acrylonitrile-styrene) are also acceptable)
A single thermoplastic resin and a laminate of individual resins (for example, a three-layer laminate of MMAAlABS and PC) can be used.

A heat ray reflective film is composed of a film base and a heat ray reflective film formed on the back surface of the film base. Its thickness is usually about 50μ to 100μ. Note that the heat ray reflective film can be formed by, for example, a known vacuum film forming method.

In the present invention, the plate-shaped resin glass and the film substrate are provided with a portion where they are brought into direct contact and a portion where they are brought into indirect contact via a heat ray reflective film. for that purpose,
For example, when forming the heat ray reflective film, it is preferable to use a suitable mask and form the heat ray reflective film in a mesh shape (claim 2) or slit shape (claim 3). Note that the heat ray reflective film has a mesh shape,
The shape is not limited to the slit shape, and any shape can be used as long as the plate-shaped resin glass and the film base can be brought into direct contact at multiple locations.

In the above, the film base is made of PC (polycarbonate), PA (polyamide), PMMA (polymethyl methacrylate), PET (bolyethylene terephthalate), etc., and the heat ray reflective film is made of AI (aluminum), Cr (chromium), etc. (Nickel), AU (gold), A
A multilayer film made of a combination of g (silver), Zn (zinc), and oxide films of individual metals can be used.

Furthermore, on the surface of the film base, a hard coat film with a thickness of about 3 μm to 10 μm is coated with epoxy resin, acrylic resin,
It may also be formed by applying a hard coat agent such as amine resin or polysiloxane. At that time, in order to improve the adhesion between the film base and the hard coat film, it is preferable to apply a primer coating to the surface of the base as necessary.

The adhesion between the sheet resin glass and the heat ray reflective film is as follows:
For example, this can be done by continuously guiding the plate-shaped resin glass and the heat ray reflective film between a pair of heat rollers, and heating and pressurizing the heat rollers to fuse them together. Here, the heating temperature, pressing force, and speed of movement between the heated rollers are determined depending on the type of resin material and the required strength of fusion.

Alternatively, the above bonding can be performed by placing a heat ray reflective film in the mold and injecting resin glass into it.

[Example] The present invention will be described below based on specific examples.

FIG. 1 is a schematic cross-sectional view of an example of the present invention, and FIG. 2 is an explanatory diagram of a method for manufacturing heat ray reflective resin glass of this example.

As shown in the figure, the heat-reflecting resin glass of this embodiment is composed of a plate-shaped resin glass 7 and a heat-reflecting film 6 adhered to the surface of the plate-shaped resin glass 7.

Here, the heat ray reflective film 6 includes a film base 60,
Heat ray reflection I formed on one surface of the film base 6o! 6
1 and a hard coat layer 62 formed on the other surface of the film base 60, and the side on which the heat ray reflective film 61 is formed is fused to the plate-shaped resin glass 7.

The heat ray reflective resin glass of this example was manufactured as follows.

(a) Heat ray reflective film 6 First, a mesh-like heat ray reflective film 61 is formed on the film base 60 by vapor deposition or sputtering, and this is set on the heat ray reflective film feeding roller 5.

Here, the film base 60 is made of polycarbonate (
PC), and Ti1t and A as the heat ray reflective film 61.
A three-layer structure film of (1) and Ti02 was used. Note that the surface of the film base 60 and the above-mentioned heat rays (g)1
The surface on the side on which the film 61 was not formed was previously subjected to hard coat treatment to form a hard coat WJ62.

(b) Plate resin glass 7 In parallel to the step (a) above, the hopper 1 of the extruder 1
The raw material resin (polycarbonate) is supplied from die 2.
A plate-shaped resin glass 7 is extruded from the glass and is taken by a taking-off device 3.

(C) The heat ray reflective film 6 is guided from the heat ray reflective film delivery roller 5 in the early stage of fusion bonding, and the plate-shaped resin glass 7 is guided between the heat rollers 41 and 42 from the take-up device 3, respectively. The heat ray reflective film 6 and the plate-shaped resin glass 7 were continuously fused together by heating and pressurizing the heat rays at a temperature of .42 mm.

Moreover, the fusion surface of the heat ray reflective film 6 was the surface on which the heat ray reflective film 61 was formed, as shown in FIG.

The heat ray reflective resin glass of this example manufactured in this manner has the following advantages.

First, since the heat ray reflective film 61 is mesh-shaped,
Adhesion between the film base 60 and the plate-shaped resin glass 7 is good.

Second, since the heat ray reflective film 61 is sandwiched between the plate-shaped resin glass 7 and the film base 60, the heat ray reflective film 61 is prevented from being damaged or attacked by chemicals.

Thirdly, the hard coat film 62 prevents the surface from being scratched.

Fourthly, the heat ray reflective film 6 prevents cracking and damage.

Fifth, since it is made of resin, it can be formed into a curved shape, and it is also easy to process holes and the like.

Sixthly, the mesh-like heat ray reflective film provides a design effect.

(Evaluation) The heat ray reflective function of the heat ray reflective resin glasses of the above examples was evaluated. The results are shown in FIG.

As can be seen from FIG. 3, the heat ray reflective resin glass of this example has good resistance in the infrared region! ) has one function.

[Effects of the Invention] In summary, the present invention provides a heat ray reflective resin glass in which the adhesive force between the film base and the plate resin glass is strengthened by forming the heat ray reflective film into a mesh shape or a slit shape. It is.

As is clear from the examples described, in the heat ray reflective resin glass of the present invention, since the film base and the plate-shaped resin glass are in direct contact with each other at many parts, the adhesive strength between the two is strong. It is.

Further, since it is made of resin, it can be formed into a curved shape, and processing such as hole drilling is also easy. .

Further, since the heat ray reflective film is sandwiched between the plate-shaped resin glass and the film base, the heat ray reflective film is prevented from being damaged or attacked by chemicals.

Furthermore, the heat reflective film prevents cracking and damage.

[Brief explanation of the drawing]

FIG. 1 is a schematic cross-sectional view of a heat ray reflective resin glass according to an example of the present invention, and FIG. 2 is an explanatory diagram of a method for manufacturing the heat ray reflective resin glass according to the example. FIG. 3 is a graph comparing the heat ray reflection function of the heat ray reflection resin glass manufactured by the method of the example and the resin glass without a heat ray reflection film. 1...Extruder 2...Die 3...Take-off device 41.42...Heat roller 6...Heat ray reflective film 7...Plate resin glass

Claims (3)

[Claims] (1) A plate-shaped resin glass, a film substrate adhered to the surface of the plate-shaped resin glass, and a heat ray reflector formed on the back surface of the film substrate and arranged between the plate-shaped resin glass and the film substrate. A heat ray reflective resin glass comprising a film, wherein the adhesion of the film substrate to the surface of the plate-shaped resin glass is performed by bringing the film substrate into direct contact with the surface of the plate-shaped resin glass. 1. A heat ray reflective resin glass characterized in that a heat ray reflective resin glass has a coexistence of a portion where the heat ray reflection is performed indirectly through the heat ray reflective film. (2) The heat ray reflective resin glass according to claim 1, wherein the heat ray reflective film has a mesh shape. (3) The heat ray reflective resin glass according to claim 1, wherein the heat ray reflective film has a slit shape.