JPH0542466Y2 - - Google Patents

Description

[Detailed Description of the Invention] <Industrial Application Field> The invention of the present application relates to an improvement of a reflective sheet with a transparent pattern.

<Prior art> Conventionally, reflective sheets used for road signs, automobile license plates, etc. have a mark printed on a part that cannot be easily erased, such as the back side of the top sheet 1, to prevent counterfeiting. It was hot.

Further, the reflectance of the printed mark portion inevitably deteriorates, resulting in a problem that the reflective performance of the reflective sheet as a whole deteriorates.

<Problems to be solved by the invention> For example, there is a retroreflective sheet as seen in Japanese Patent Application Laid-Open No. 10102/1983. This invention relates to a method for manufacturing a wide-angle retroreflective sheet, and has the following configuration. That is, (a) a transparent base film (a paint with adhesive properties that forms stretchable wrinkle-like irregularities when dried by heating) is applied to the upper surface of a release sheet that is insensitive to the transparent base film using a coating machine or other appropriate equipment; smear.

(b) By removing a large number of microscopically minute transparent spheres from the upper surface of the transparent base film while it is still wet, or by embedding the lower hemisphere of the spheres in the transparent base film by using other appropriate methods. A retroreflective layer made of transparent spheres is formed by adhering.

C. Next, the transparent base film is heated and dried while being expanded and contracted to form wrinkle-like unevenness on its upper surface.At the same time, the transparent base film surface is also formed on the retroreflective layer of the transparent spheres adhered to it. The unevenness of the shape corresponding to this is formed along this.

D. Afterwards, apply a transparent focusing film (similar to the transparent base film, but the irregularities formed by the stretching movement are smaller than this film) using the same method as the transparent base film was applied to the surface of the release sheet. Paint) is applied to the upper hemisphere of each transparent sphere that forms the retroreflective layer exposed to the outside air.
This film is heated and dried while being expanded and contracted, and by the contraction movement of the transparent focal point, microscopically extremely minute irregularities made of this film are formed on the upper hemisphere surface of each of the spheres. At the same time, this contraction movement causes the upper hemisphere surface of the ball to be covered with the transparent focusing film in a concentric arc shape of uniform thickness.

E. Afterwards, a reflective reinforcing device having a reflective power of a metal or a different color is laminated on the uneven surface of the transparent focusing film so that the lower surface has a shape that matches this, and a release sheet is placed on the lower surface of the transparent base film. The transparent base film that has been removed and exposed to the outside air is used externally.

However, in the case of sheets manufactured in this way, the transparent focusing film and reflective reinforcing device follow the undulating surface shape of the transparent base film, so the surface of the sheet is
This makes these undulations stand out on the surface. Further, the small irregularities formed at the interface between the transparent focusing film and the reflective reinforcing device are also made to stand out on the sheet surface side in the same shape as the irregularities.

Therefore, by taking the shape of the undulations on the sheet surface side (the surface of the reflective reinforcing device), it is possible to easily imitate the shape formed by the undulations.

Another method for achieving such a three-dimensional visual effect is the retroreflective sheet disclosed in Japanese Patent Application Laid-Open No. 54-50085.

However, even in this case, the entire sheet is embossed, and the shape can be easily formed from the outside. Here, the fact that the raised portion is white also includes the problem of inhibiting light transmission.

The provision of unevenness in the light transmitting portion can also be seen in other industrial fields of application. For example, the instrument operation panel shown in Japanese Utility Model Application Publication No. 161895/1989 has undulations formed on the surface of a transparent plate by embossing, although the basic structure is different from that of a retroreflective sheet. is shown.

However, this undulation is exposed to the outside and can be easily counterfeited, which is the same as that disclosed in the above-mentioned conventional publications.

Regarding the reflexive sheet, a convex protruding portion is also shown in the sheet shown in Japanese Utility Model Application Publication No. 59-9848, although the industrial field of use is further different. However, it can be easily imitated by removing the illumination box and cutting out the recesses on the ink-applied side of the textured sheet.

Regarding the prevention of counterfeiting by external shaping, for example, a method for manufacturing a retroreflective sheet is known, as disclosed in Japanese Patent Publication No. 56-2921, which has the following configuration.

That is, a transparent and smooth surface coating layer is formed into two layers, and a printed part is provided between the two layers, in which printing is performed with a line having a thickness of 0.5 mm or less, and then the surface coating layer is A binder layer is provided on the back surface of the transparent sphere layer, and a large number of small transparent spheres are embedded in the binder layer to form a transparent sphere layer, and then the remainder of the transparent sphere layer is covered with a transparent interstitial layer, and the interstitial layer is A method for producing a retroreflective sheet, characterized in that a reflective layer is formed on the back surface of the retroreflective sheet so as to have a curved surface concentric with the small transparent spheres.

The reflective sheet obtained by this method has a flat printed part between the two surface film layers, so it is impossible to imitate the printed content by taking the shape from the outside. It has become a thing.

However, in this case, the presence of the printing portion hinders the transmission of light into the sheet, resulting in a decrease in brightness.

As described above, nothing has yet been proposed that solves the conflicting problems of preventing forgery and preventing reduction in brightness, and the present invention aims to solve these problems.

<Means for Solving the Problems> Therefore, the present invention adopts the following configuration in a retroreflective sheet with a transparent pattern used for road signs and automobile license plates.

That is, in order from the surface, the transparent sheet 11,
a transparent resin film layer 12, a transparent reflective coating 3, a transparent binder resin 4, a transparent focus coating 6,
A reflective film 7 that reflects light is laminated. Then, an appropriate number of glass beads 5 are interposed at appropriate positions on the interface between the binder resin 4 and the focal film 6, and the surface of the transparent sheet 11, the interface between the transparent sheet 11 and the resin film layer 12, and the resin film layer 12 are reflected. The interface of the coating 3,
The interface between the reflective coating 3 and the binder resin 4 and the interface between the binder resin 4 and the focal coating 6 are, as a whole, planes with no undulations or curvature, and a transparent pattern is formed only locally on the reflective coating 3. The undulations of the unevenness 31 are formed on the interface between the resin film layer 12 and the reflective coating 3, and on the reflective coating 3.
and the interface between the transparent sheet 11 and the resin film layer 12, the interface between the binder resin 4 and the focal film 6, and the glass beads 5.
It is characterized in that it does not reach a certain position and maintains the above-mentioned plane as a whole.

<Function> In the retroreflective sheet of the present invention having the above means, the transparent sheet 11 forming the surface of the sheet
and a reflective film 7 forming the surface of the sheet and the back surface of the sheet.
The shape of the irregularities 31 exhibiting a transparent pattern formed locally on the reflective coating 3 is not undulating, and cannot be faked by simply taking the shape from the outside.

On the other hand, since the transparent unevenness 31 exhibits a pattern, the transmittance of light is not impaired.

Furthermore, the light reflected from the reflective film 7 passes through the surface and the planar interface between each layer up to the surface and passes through the unique transparent pattern exhibited by the transparent unevenness 31 to the outside, resulting in a three-dimensional It is possible to obtain a unique visual effect of exposing the pattern from a flat surface. Furthermore, since the unevenness 31 is provided only in local areas of the reflective coating 3, which is flat on both the front and back sides, the pattern is not displayed in contrast to other areas of the reflective coating 3 that have no undulations. As a result, its visibility has been significantly increased.

Furthermore, since the sheet surface is flat, dirt and dust are difficult to adhere to, and accumulated dust and dirt can be easily removed.

<Example> FIG. 1 shows an example of the present invention. As shown in FIG. 1, this embodiment is a retroreflective sheet that reflects reflected light in the same direction, and has a top sheet 1 on its surface.

The top sheet 1 is made by coating a resin film layer 12 on a single transparent sheet 11, embossing the resin film layer 12 by heating and pressing with a hologram original plate, and then depositing a transparent reflective coating 3 on top of the resin film layer 12. It is something.

The embossed resin film layer 12 has a thickness of about 30 μm, and the transparent reflective coating 3 is suitably made of, for example, zinc sulfide, but may be changed to another material as appropriate.

Moreover, the refractive index of this reflective coating 3 is the same as that of the resin film layer 12.
It is desirable that there is a difference of 0.1 or more, preferably 0.5 or more, and in the case of a metal reflective film such as aluminum, it is 300 Å.
The following is desirable.

Of course, a protective sheet may be provided on the resin film layer 12 side separately from the above example.

The pattern of the surface sheet 1 formed in this way is invisible when viewed from above because light A passes through it, but light B coming from a predetermined direction is exposed to the unevenness 31 on the embossed surface. It reflects and makes the pattern stand out.

Note that normally, lights A and A' are within 5 degrees of observation angle, light B,
B′ is an incident angle of 5° or more.

More specifically, as shown in FIG. 1, the sheet of this example includes, in order from the surface, a transparent sheet 11, a transparent resin film layer 12, a transparent reflective coating 3, a transparent binder resin 4, and a transparent resin film layer 12. A focal film 6 and a reflective film 7 that reflects light are laminated. Then, an appropriate number of glass beads 5 are interposed at appropriate positions on the interface between the binder resin 4 and the focal film 6, and the surface of the transparent sheet 11, the interface between the transparent sheet 11 and the resin film layer 12, and the resin film layer 12 are reflected. The interface of the coating 3,
The interface between the reflective coating 3 and the binder resin 4 and the interface between the binder resin 4 and the focal coating 6 are, as a whole, planes with no undulations or curvature. However, unevenness 31 exhibiting a transparent pattern is formed only locally on the reflective coating 3, and the undulations of the unevenness 31 reach the interface between the resin film layer 12 and the reflective coating 3, and the interface between the reflective coating 3 and the binder resin 4. Ori,
The interface between the transparent sheet 11 and the resin film layer 12, the interface between the binder resin 4 and the focal film 6, and the position of the glass beads 5 are not reached, and the above-mentioned plane is maintained as a whole.

Next, the manufacturing method will be explained.

A transparent sheet 11 is placed on a PET film 10 (75μ is optimal), and a resin film layer 12 is placed on top of it.
Coat approximately 30μ.

Embossing is performed on the coated resin film layer 12 by heating and pressing with a hologram original plate,
Irregularities 31 are added to the surface corresponding to the patterned portion.

A transparent reflective film 3 of about 150 Å is coated on the embossed resin film layer 12.

A binder resin 4 is coated on the transparent reflective coating 3, and a sphere with a diameter of about 50~ is coated on top of it.
Embed half of glass beads 5...5 with a diameter of 60μ and a refractive index of approximately 2.25.

A focal film 6 is formed on the glass beads 5...5.
Coat approximately 15μ.

Focus film 6 is made of aluminum, vacuum level is 2×10 ^-4
The reflective film 7 is formed by vacuum deposition to a thickness of 600 to 800 Å at about Torr.

Peel off the PET film 10.

The above is an example.

Next, the path of the light A passing through the topsheet 1 will be explained as follows.

Light A that has passed through the topsheet 1 enters the binder resin 4 and hits the glass beads 5. The light A hitting the glass beads 5 is condensed by the glass beads 5, passes through the focusing film 6, hits the aluminum reflective film 7, and is reflected.

The light A' that hits the reflective film 7 and is reflected returns at the same angle as when it was incident. (referred to as retroreflection). Since the retroreflected light is more powerful than the hologram image, the hologram image B' cannot be seen even if the other light B is within the hologram reproduction angle range.

Of course, since the angle of the retroreflected light is different from the angle at which the hologram is reproduced, the intensity of the retroreflected light hardly decreases.

The above is an example of the invention of the present invention, and the structure is not limited to this. It is also possible to have a plurality of resin film layers 12, or to coat the reflective coating 3 only on the uneven portions 31 of the embossed surface. good.

Further, the thickness of the reflective coating 3 may be changed as appropriate so that only light of a certain wavelength is reflected, and the original plate for embossing may be replaced with the hologram original plate and another original plate may be used as appropriate.

<Effects of the invention> Since the patterned retroreflective sheet of the present invention reflects only incident light at a predetermined angle or light of a predetermined wavelength at the reflective coating portion of the top sheet, the retroreflection performance is not impaired.

In addition, since the surface sheet has embossed irregularities and a transparent reflective film, which is difficult to manufacture while maintaining a flat surface, it can be made into a retroreflective sheet that is difficult to counterfeit.

As described above, the present invention provides a useful and practical retroreflective sheet.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing an embodiment of the present invention. DESCRIPTION OF SYMBOLS 1... Surface sheet, 3... Reflective coating, 4... Binder resin, 5... Glass beads, 6... Focusing film, 7... Reflective film, 11... Transparent sheet, 12
...Resin film layer, 31...Irregularities.

Claims (1)

[Scope of claim for utility model registration] In a retroreflective sheet with a transparent pattern used for road signs and automobile license plates, in order from the surface: a transparent sheet 11, a transparent resin film layer 12, a transparent reflective coating 3. A transparent binder resin 4, a transparent focal film 6, and a reflective film 7 that reflects light are laminated, and an appropriate number of glass beads 5 are interposed at appropriate positions at the interface between the binder resin 4 and the focal film 6. The surface of the transparent sheet 11, the interface between the transparent sheet 11 and the resin film layer 12, and the resin film layer 12
The interface between the reflective coating 3 and the reflective coating 3, the interface between the reflective coating 3 and the binder resin 4, and the interface between the binder resin 4 and the focal coating 6 are, as a whole, planes with no undulations or curvature. Irregularities 31 exhibiting a transparent pattern are formed only locally, and the undulations of these recesses and recesses 31 reach the interface between the resin film layer 12 and the reflective coating 3 and the interface between the reflective coating 3 and the binder resin 4, and the transparent sheet 11 and the resin film layer 12, the interface between the binder resin 4 and the focal film 6, and the position where the glass beads 5 are located, and the above-mentioned flat surface is maintained as a whole. Transparent patterned retroreflective sheet.