JP5909313B2 - Retroreflective indicator - Google Patents

Description

  The present invention relates to a retroreflective display that is viewed three-dimensionally from a vehicle traveling with a headlamp turned on.

  For retroreflective displays that reflect the irradiated light in the irradiation direction, arrows are displayed on the side of the road to recognize the direction of guidance, and multiple lines of sight are arranged along the road to recognize the alignment of the road. Guide marks and the like are often used, and various inventions are disclosed.

  For example, Patent Document 1 discloses a sign plate that is used by being attached to a road sign lamp for guiding the progress of a traveling area at a construction site or the like, and has an appropriate size and indicates a guiding direction on the surface side. A rectangular resin reflective pout is formed by dividing it into two upper and lower parts of the same shape by marking an arrow or a restriction symbol such as right / left turn prohibition or parking prohibition, and to the back side of the two reflection plates A stopper that is locked in a flat state is provided, and this is foldably coupled with a hinge. In addition, a taper that spreads the hooking belt slightly downwards to the substantially central side of the upper plate on the back side of the two upper and lower plates. And the both ends of the plate are fixed to each other, and the inner surface of the plate is foldable by the hinge located at the center in the width direction of the plate. Sex sign board, disclosed It has been.

Japanese Utility Model Publication 2-45899

  However, the retroreflective marking plate as in Patent Document 1 is designed to indicate the guidance direction by marking arrows or regulatory symbols on a reflective plate that is reflected and shines with good visibility even at night. Since it is drawn with flat letters and figures, it may be overlooked without alerting the vehicle especially at high speed.

  Therefore, the present invention provides a highly attractive retroreflective display that can attract high attention even at night.

In order to achieve the above object, the present invention is configured as follows.
That is, the retroreflective display according to the present invention includes a three-dimensional shape in which a display is drawn, and the display is formed by combining a plurality of display areas in a planar shape.
The plurality of display areas include a display area that expresses a bright part of the stereoscopic view shape, a display area that expresses a shadow of the stereoscopic view shape, and a display area that expresses a background part of the stereoscopic view shape,
The display area expressing the bright part of the three-dimensional shape is formed with a light transmittance larger than the display area expressing the shadow of the three-dimensional figure shape and the display area expressing the background part of the three-dimensional shape, and The light that is transmitted through the display area that represents the bright part of the figure shape and retroreflected to the rear reflector, is transmitted through the display area that represents the background part of the three-dimensional diagram shape and is retroreflected to the rear reflector. It is characterized in that the light is made stronger than the emitted light and expressed in the light irradiation direction .

According to the retroreflective display according to the present invention, a road display is drawn on the front surface of the reflector having retroreflectivity, and the road display is formed by combining a plurality of display areas having different light transmittances in a planar shape, The light that passes through each display region and is retroreflected by the reflector is emitted as reflected light from each display region, so that the intensity of light is different from one retroreflective display. The reflected light is visually recognized, and a highly attractive display can be performed.
In addition, the road display includes a three-dimensional shape formed by combining a plurality of display areas having different light transmittances in a planar shape, and due to a difference in reflection luminance in each display area resulting from the difference in light transmittance, Since the shadow of the three-dimensional figure shape is expressed, the bright part in the three-dimensional figure shape is expressed by the strong reflected light of the display area with high reflection luminance, and the shadow part is weakly reflected light of the display area with low reflection luminance. Alternatively, it is expressed without reflection, and the three-dimensional figure shape is made to be viewed more three-dimensionally, and it is possible to perform a highly attractive display that is easier to call attention.

  In addition, each display area is colored with a different brightness, and in addition to the difference in the intensity of light retroreflected in each display area, the shadow of the three-dimensional shape is expressed by the difference in brightness. Then, the three-dimensional figure shape can be visually recognized in the daytime to draw attention, and the difference in the intensity of the reflected light due to the difference in the reflected luminance and the difference in the brightness of the colored color tone at night, The three-dimensional shape is visually recognized so as to make the three-dimensional effect synergistically, and a highly attractive display can be performed, which is preferable.

  According to the retroreflective display according to the present invention, it is possible to perform a highly attractive display capable of raising a high alert even at night.

It is a front view which shows one Embodiment of the retroreflective display body which concerns on this invention. It is a figure which shows the outline | summary of the AA cross section of FIG. 2 is a table showing colors, lightness of color tone, and light transmittance of each display area in FIG. 1. It is a figure which shows the outline | summary of the cross section of other one form of implementation of the retroreflection display body which concerns on this invention.

Embodiments of the present invention will be specifically described with reference to the drawings.
Reference numeral 1 denotes a retroreflective display.
The retroreflective display 1 of the present embodiment has a retroreflectivity that reflects light incident from the front surface in the irradiation direction, and is formed in a rectangular plate shape with rounded corners.
In the retroreflective display 1 of the present embodiment, a three-dimensional arrow indicating the right direction is displayed on the front side, and specifically, display regions 6a to 6d colored in different color tones are displayed. The display area 6a represents the arrow part, the display areas 6b and 6d represent the shaded part of the arrow, and the display area 6c arranged around the display area 6b represents the background part of the arrow.
The arrow display of the retroreflective display body 1 of the present embodiment is assumed to be a road display that is fixed to a support column or a wall surface, is erected on the side of the road, and is used to alert the presence of a curve or the like. Designed. By providing the display areas 6b and 6d so as to represent the shaded part of the arrow, the arrow part represented by the display area 6a is visually recognized as floating from the background part by the display area 6d, and the arrow display is displayed in three dimensions. Is done.
The retroreflective display 1 according to the present embodiment displays a three-dimensional arrow display. However, the display content is not limited to this, and other symbols and characters, information displays, marks, and the like can be displayed in three dimensions. It may be represented by a figure shape. Moreover, it may represent only the display of the three-dimensional diagram shape, and may be displayed on the retroreflective display body 1 together with the display of the three-dimensional diagram shape and the display visually recognized in plan view.

Reference numeral 2 denotes a reflector.
The reflector 2 includes a base material 21 and a retroreflective layer 22.
The base material 21 is formed in the same shape as the retroreflective display body 1 and functions as the base body.
Although the base material 21 of this embodiment is formed with aluminum, it is not restricted to this, Hard materials, such as other metals, such as iron and stainless steel, synthetic resins, wood, and glass, can be used suitably. Further, a material such as a flexible sheet-like synthetic resin or cloth can be used.

The retroreflective layer 22 provides the retroreflective display 1 with light retroreflectivity.
The retroreflective layer 22 of the present embodiment is formed of a sheet having retroreflectivity. Specifically, the retroreflective layer 22 is adhered to the front surface of the base material 21 over the entire surface. Is provided.
As an example, the retroreflective sheet for forming the retroreflective layer 22 has a configuration in which a retroreflective component such as glass beads is enclosed inside the sheet, or a configuration in which a prism element such as a cube corner prism is formed inside the sheet. In this embodiment, a white retroreflective sheet in which cube corner prism elements are formed inside the sheet is used.

Reference numeral 4 denotes a display layer.
The display layer 4 of the present embodiment includes a transparent base sheet 41 and a colorant 42 that adheres to the surface thereof.
The base sheet 41 is made of a transparent synthetic resin, and the back side is pasted over the entire surface of the retroreflective layer 22 with an adhesive, and the surface side is processed to improve the adhesion of the colorant 42. It has been subjected.
More specifically, the base sheet 41 of the present embodiment is formed of a transparent ink jet printing sheet processed so that ink jet printing can be suitably performed on the surface.

The colorant 42 adheres to the surface of the base sheet 41 to form the display areas 6a to 6d.
For the colorant 42 of this embodiment, four colorants 42a to 42d having different color tones are used, and are attached to the base sheet 41 to form the display areas 4a to 4d.
The colorants 42a to 42d of the present embodiment are each formed from a translucent coating film in which ink is applied and dried by ink jet printing. In FIG. 2, the colorant 42c is applied to the upper half. The display area 6c is formed, and the display area 6a with the colorant 42a applied to the lower half is formed.

Reference numeral 5 denotes a protective sheet.
The protective sheet 5 is formed of a transparent synthetic resin, and is adhered to the entire surface of the display layer 4 with an adhesive.
The protective sheet 5 physically protects the display composed of the display areas 4a to 4d formed by the colorants 42a to 42d of the display layer 4 from articles coming into contact with the outside, and the protective sheet 5 contains an ultraviolet absorber. By doing so, fading of each display area 4a-4d by irradiation of sunlight etc. is suppressed, and the weather resistance of the retroreflective display 1 is improved.
The protective sheet 5 is not particularly limited as long as it is transparent, but is preferably a film formed using a synthetic resin that is unlikely to deteriorate such as discoloration when installed outdoors. The protective sheet 5 of the present embodiment is a fluorine-containing film. It is formed using a resin.

FIG. 3 is a table showing the color, lightness of color tone, and light transmittance of the display areas 6a to 6d in FIG. The lightness values shown in FIG. 3 are the lightness values in the Munsell value, where ideal white that reflects 100% of light is lightness 10 and ideal black that absorbs 100% of light is 0, The interval is shown in 11 levels divided into 10 equal parts.
As shown in FIG. 3, the display areas 6a to 6d are formed in yellow, light blue, blue, and dark blue, respectively, so that the arrow display represented by the display area 6a can be viewed three-dimensionally. However, as shown in FIG. 3, the brightness of each of the display areas 6a to 6d is provided at 8.0, 6.0, 4.0, and 2.0, respectively, so that the brightness difference is about 2 respectively. Is provided.
It is preferable to set the brightness difference between the display areas 6a to 6d to 2 or more because the brightness difference can be easily recognized as a shadow.
In addition, the lightness of 0 and 1 is too black, and the lightness of 9 and 10 is too white, and the hue of each of the display regions 6a to 6d is adjusted to be 2 or more and 8 or less. Yes.

In the retroreflective display 1 of the present embodiment, the base sheet 41 and the protective sheet 5 disposed on the front side of the retroreflective layer 22 are formed of a transparent sheet, and each colorant 42a attached to the base sheet 41 is used. Since each of .about.42d is formed in a semi-transparent layer, the light irradiated from the front of the retroreflective display body 1 is transmitted through the retroreflective display layer 22 and retroreflected to radiate reflected light toward the light source. It is made to be done.
Further, the display areas 6a to 6d formed by the adhesion of the colorants 42a to 42d are formed so as to have different light transmittances. Thus, the display areas 6a to 6d through the reflector 2 are formed. A difference is made in the reflected luminance, and the light incident on each of the display areas 6a to 6d is retroreflected as reflected light having an intensity corresponding to the reflected luminance.

As shown in FIG. 3, the light transmittances of the display regions 6a to 6d are formed to be maximum, large, medium, and small, respectively, which is the lightness of the color tone of the display regions 6a to 6d. It is formed corresponding to the size.
That is, a light color display area with a large lightness value has a large light transmittance, and a dark color display area with a small lightness value has a low light transmittance.
As described above, the display areas 6a to 6d of the present embodiment are provided in correspondence with the light transmittance and the brightness of the color tone, but the retroreflective display body 1 of the present embodiment has the above-described configuration. Thus, a three-dimensional arrow display is represented by the brightness difference of the color tone of each display area 6a-6d. For this reason, when light is irradiated from the front at night or the like and the reflected light is retroreflected, each reflected light that has entered the display regions 6a to 6d and retroreflected is reflected by different light transmittances. A difference in intensity of reflected light is caused by a difference in luminance, and a three-dimensional arrow display is also expressed by the difference in intensity of reflected light. Therefore, an arrow by the retroreflective display 1 is used. The display is highly attractive to be viewed three-dimensionally not only in the daytime but also at night.
When the light transmittances of the display areas 6a to 6d are formed to be equal and have the same reflection luminance, the reflected lights that are incident on the display areas 6a to 6d and retroreflected have the same intensity. Although there is a possibility that the display displayed on the display layer 4 is difficult to visually recognize due to the reflected light, the retroreflective display body 1 of the present embodiment varies the light transmittance of each of the display regions 6a to 6d. As a result, a difference is produced in the reflected luminance, and this is prevented. In addition, the display of the display layer 4 can be easily recognized by the difference in intensity of the reflected light due to the difference in reflected luminance, and the reflected light can display an arrow by expressing the shadow of the three-dimensional shape shown in the display layer 4. It is provided so that it can be viewed in three dimensions.

Moreover, since each colorant 42a-42d which forms each display area 6a-6d of this embodiment is formed in the semi-transparent layer shape, when light is irradiated from the front, each colorant 42a-42d is applied. The reflected light and the light transmitted through the colorants 42a to 42d and retroreflected by the retroreflective layer 22 both make the color tone of the colorants 42a to 42d vividly visible.
For this reason, the reflected light which is irradiated from the front of the retroreflective display 1 and retroreflected is added to the display areas 6a to 6d in addition to the difference in light intensity corresponding to the light transmittance of the display areas 6a to 6d. Since the three-dimensional effect of the display is synergistically increased and visually recognized by the brightness difference of the color tone of 6d, the display by the retroreflective light of the retroreflective display body 1 can be made more attractive.

  The display areas 6a to 6d of the present embodiment are formed so that the color and lightness of the color tone are as shown in FIG. 3. This is because the colors, transparency, and layers of the colorants 42a to 42d are as follows. The color tone of each of the display areas 6a to 6d is adjusted according to the thickness of the display.

  The retroreflective display 1 of the present embodiment is provided with a retroreflective layer 22 in which a retroreflective sheet is attached to a base material 21 to impart retroreflectivity to the reflector 2, but the present invention is not limited thereto. Alternatively, retroreflective coating may be applied to the base material 21 to form the retroreflective layer 22, and the base material 21 is formed of a retroreflective plate or sheet to retroreflect the base material 21 itself. It may be formed on the reflector 2 having the property, or another method may be used.

Further, the retroreflective display 1 of the present embodiment is provided so that the light transmittance of each of the display areas 6a to 6d is not zero even in the smallest display area 6d, but light is transmitted. However, the present invention is not limited to this, and a display region where the light transmittance is zero may be provided. However, retroreflective light is reflected from the entire surface of the retroreflective display 1 by providing all the display areas so as to transmit light as in the present embodiment. Since the visibility of the whole of 1 can be made favorable, it is preferable.
In addition, the display areas 6a to 6d of the present embodiment are configured such that when the headlight of the car is retroreflected by the reflector 2, the reflected light is bright enough to visually recognize the arrow displayed by the driver. The respective light transmittances are adjusted so as to be reflected so as to obtain an appropriate reflection luminance.

FIG. 4 is a diagram showing an outline of a cross section of another embodiment of the retroreflective display 1 according to the present invention.
In the retroreflective display 1 of the present embodiment, each of the colorants 42a to 42d attached to the base sheet 41 is electrostatically printed in a dot pattern in which opaque and fine dots are arranged side by side instead of a translucent layer. This is the main point that is different from the embodiment shown in FIG.
Specifically, the dot patterns formed by the colorants 42a to 42d are printed so that the gap regions 43a to 43d are formed between the dots, and the display regions 6a to 6d are formed, respectively. It has been.
In FIG. 4, a display area 6c is formed by a colorant 42c applied in a dot shape in the upper half and a gap area 43c therebetween, and a colorant 42a applied in a dot shape in the lower half and a gap area 43a therebetween. The state where the display area 6a is formed is shown.

  The display areas 6a to 6d of the present embodiment are formed to have the same color and lightness of the color tone as shown in FIG. This depends on the color of each colorant 42a to 42d, the dot shape and size of the dot pattern, the balance with the color tone of the retroreflective layer 22 by adjusting the size of the gap regions 43a to 43d, etc. The color tone of 6a to 6d is adjusted.

When the retroreflective display 1 of the present embodiment is irradiated with light from the front, this light passes through the gap regions 43a to 43d and reaches the retroreflective layer 22, and the reflected light retroreflected by this is again the gap region. The light passes through 43a to 43d and is emitted toward the light source.
The light transmittances of the display areas 6a to 6d of the present embodiment are formed to be the same as those shown in FIG. 3, which are gap areas 43a to 43d formed between the dots of the colorants 42a to 42d. And the area ratio between the colorants 42a to 42d and the gap regions 43a to 43d.

The colorants 42a to 42d of the present embodiment are provided in a dot pattern in which fine dots are arranged side by side in the vertical and horizontal directions. However, the colorants 42a to 42d are not limited to this as long as they have gap regions 43a to 43d, respectively. You may provide in the stripe pattern printed so that a line may be arranged in parallel, and you may provide in another pattern.
In addition, each of the colorants 42a to 42d of the present embodiment may be provided in a semitransparent dot pattern or the like, and a semitransparent colorant and an opaque colorant may be selected or combined to adhere to the base sheet 41. .

DESCRIPTION OF SYMBOLS 1 Retroreflective display body 2 Reflector 21 Base material 22 Retroreflective layer 4 Display layer 41 Base sheet 42 Colorant 42a-42d Colorant 43a-43d Crevice area 6a-6d Display area

Claims (3)

A display is drawn, and the display includes a three-dimensional shape formed by combining a plurality of display areas in a planar shape,
The plurality of display areas include a display area that expresses a bright part of the stereoscopic view shape, a display area that expresses a shadow of the stereoscopic view shape, and a display area that expresses a background part of the stereoscopic view shape,
The display area expressing the bright part of the three-dimensional shape is formed with a light transmittance larger than the display area expressing the shadow of the three-dimensional figure shape and the display area expressing the background part of the three-dimensional shape, and The light that is transmitted through the display area that represents the bright part of the figure shape and retroreflected to the rear reflector, is transmitted through the display area that represents the background part of the three-dimensional diagram shape and is retroreflected to the rear reflector. A retroreflective display body characterized in that the light is made stronger than the emitted light and expressed in the light irradiation direction . Each display area is colored with a different brightness, and in addition to the intensity of the retroreflected light in each display area, the shade of the three-dimensional shape is expressed by the difference in brightness. The retroreflective display according to claim 1. The display area expressing the shadow of the three-dimensional map shape and the display area expressing the background portion of the three-dimensional map shape reflect light of different intensities in the light irradiation direction, respectively. Item 2 is a retroreflective display.

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