JP2012118123A - Phosphorescent retroreflective sheet having superior adhesion to rough surface - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a phosphorescent retroreflective sheet allowing visual recognition of a guide display for an escape guide at a power failure in disaster, having high workability exerting high visibility by retroreflection when light from a light source such as a flashlight is applied thereto, and being usable for rugged floors such as platforms at stations, entrances of buildings and passages, and for rugged wall surfaces.SOLUTION: In a sheet having a retroreflective layer, a phosphorescent layer is stacked on the lower surface side of the retroreflective layer via a transparent base material, a surface protective layer is stacked on the upper surface side of the retroreflective layer, and an aluminum sheet is stacked on the phosphorescent layer side of the retroreflective layer via an adhesive layer. In the phosphorescent retroreflective sheet, a total light transmittance of the surface protective layer is 80% or more, and a tear strength in the whole layer of the phosphorescent retroreflective sheet after having stacked the aluminum sheet thereon is 50 N/mm or more.

Description

  The present invention relates to a phosphorescent retroreflective sheet that can be used on floors and wall surfaces of station platforms, entrances and exits of buildings, and passages.

Conventionally, sheets containing phosphorescent materials and fluorescent pigments that emit light in the dark are known. For example, Patent Document 1 discloses a phosphorescent sheet obtained by mixing a ceramic phosphorescent material and retroreflective glass bead particles in a heat-resistant transparent silicon agent as a phosphorescent sheet having a high luminous intensity and a long phosphorescence time with a small amount of phosphorescent material. ing. However, ceramic phosphorescent material and glass bead particles are mixed in the entire sheet, and the surrounding situation can be visually confirmed, especially in preparation for a power outage in the event of a disaster. In addition, in terms of followability to uneven surfaces such as paved roads and adhesion, it was insufficient.
JP 2005-115300 A

  The present invention has been made in view of such a technical background, and is capable of visually recognizing a guidance display for evacuation guidance at the time of a disaster power outage, and further having high visibility due to retroreflection when irradiated with light from a light source such as a flashlight. An object of the present invention is to provide a phosphorescent retroreflective sheet that can be used on uneven floors and walls such as station platforms, entrances and exits of buildings, and passages, which are excellent in workability to exhibit the above.

In order to achieve the above object, the present invention provides the following means.
[1] In a sheet having a retroreflective layer, a phosphorescent layer is laminated on the lower surface side of the retroreflective layer via a transparent base material layer, and further, a surface protective layer is laminated on the upper surface side of the retroreflective layer, An aluminum sheet is laminated on the phosphorescent layer side of the retroreflective layer via an adhesive layer, the total light transmittance of the surface protective layer is 80% or more, and the phosphorescent retroreflective sheet after lamination of the aluminum sheet A phosphorescent retroreflective sheet characterized in that the tear strength in all layers is 50 N / mm or more.

  [2] In the sheet having the retroreflective layer, a print layer is laminated on the upper surface side of the retroreflective layer, and a phosphorescent layer is laminated on the lower surface side via a transparent base material layer, and further, the print layer side of the retroreflective layer A surface protective layer is laminated, an aluminum sheet is laminated on the phosphorescent layer side of the retroreflective layer via an adhesive layer, and the total light transmittance of the surface protective layer is 80% or more, and the aluminum sheet is laminated. The phosphorescent retroreflective sheet, wherein tear strength in all layers of the later phosphorescent retroreflective sheet is 50 N / mm or more.

  [3] The phosphorescent retroreflective sheet according to item 1 or 2, wherein the aluminum sheet has a thickness of 20 μm to 100 μm.

The invention [1] has the following effects.
A. Since the phosphorescent layer is laminated on the lower surface side of the retroreflective layer constituting the phosphorescent retroreflective sheet via a transparent base material layer, the phosphorescent layer emits light even in the dark, such as at the time of a disaster blackout, so that it exhibits visibility Can do.
(A) Since the surface protective layer is laminated on the upper surface side of the retroreflective layer, it is possible to protect the retroreflective layer from being damaged.
C) Since the retroreflective layer is laminated on the phosphorescent retroreflective sheet, when the light from a light source such as a flashlight is irradiated, high visibility can be exhibited by the retroreflection.
D. Since the aluminum sheet is laminated on the phosphorescent layer side of the retroreflective layer via an adhesive layer, even if there is unevenness on the floor surface, it has good trackability and excellent workability. It becomes a retroreflective sheet.
E) Since the total light transmittance of the surface protective layer is 80% or more, the design of the layer laminated on the lower surface side of the previous surface protective layer can be expressed as it is.
F. Since the tear strength in all layers of the phosphorescent retroreflective sheet after laminating the aluminum sheets is 50 N / mm or more, there is a problem that the phosphorescent retroreflective sheet is torn or torn due to frequent walking. Absent.

  In the invention of [2], in addition to the effect of the invention of [1], since the printing layer is laminated, lines, characters, figures, symbols, etc. can be displayed, and further printed on the lower surface side of the surface protective layer Since the layers are laminated, printed characters and figures can be prevented from being faded due to surface friction or the like.

  In the invention of [3], since it is a phosphorescent retroreflective sheet in which the aluminum sheets having a thickness of 20 μm to 100 μm are laminated, when laying, it is hit or pressed from above with an appropriate means such as a hammer or a roller. It can be easily deformed along the unevenness on the floor surface and wall surface of the station platform, building entrance / exit, passage, etc., and can be constructed in close contact. Also, it does not interfere with walking that is too thick.

  Hereinafter, it will be described in more detail with reference to the drawings. FIG. 1 is a schematic cross-sectional view of a phosphorescent retroreflective sheet (1) showing an embodiment of the present invention, (2) is a surface protective layer, (3) is a printed layer, (4), (6) are A transparent base material layer, (5) a retroreflective layer, (7) a phosphorescent layer, and (8) an aluminum sheet. (The adhesive layer is not shown.)

  The surface protective layer (2) and the transparent substrate layer (4), (6) in the present invention are not particularly limited. For example, the surface protective layer (2) and the transparent substrate layer (4) are composed of an olefin resin composition. Examples thereof include polyethylene resin, polybutene resin, ethylene vinyl acetate copolymer, ethylene methyl acrylate, and polystyrene resin. Further, agents such as an antistatic agent, a flame retardant, an antioxidant, an ultraviolet absorber, and a light stabilizer can be added within a range that does not impair the effects of the present invention. In addition, what is necessary is just to select the form to laminate | stack appropriately, such as a sheet | seat, a film, or apply | coating.

  Sheet formation and film formation of the surface protective layer (2) can be formed by known methods such as calendering and T-die extruder, for example. The surface protective layer (2) is formed by coating the composition of the surface protective layer (2) on the transparent substrate layer (4) or on the printed layer (3) on the transparent substrate layer (4). Can be applied directly. The composition can cure a urethane resin, an acrylic resin, or the like with ultraviolet rays or heat. Among them, a flexible resin having a stretch rate of 10 to 30% in the cured resin is preferable.

  In the phosphorescent retroreflective sheet (1) laminated with the printing layer (3), the total light transmittance of the surface protective layer (2) of the present invention is 80% or more, more preferably 90% or more. The printed layer (3) is transparent so that the printed layer (3) can be seen well, and has the effect of suppressing the attenuation of the reflection performance.

  The printing layer (3) in the present invention is formed by printing on the transparent substrate layer (4) or under the surface protective layer (2). As a printing method, for example, it can be formed by drawing a pattern with a screen printer, an inkjet printer or the like. In addition, any pattern may be drawn as a pattern. For example, if it is a phosphorescent retroreflective sheet used on a station platform, it can be used as guidance for emergency evacuation. In the case of using in, a figure or a character indicating an emergency exit, guidance for guidance, or the like can be considered.

  The retroreflective layer (5) in the present invention may be provided with a layer formed by arranging transparent spheres in one layer and a reflective material. For example, glass beads are used as the transparent spheres. What is necessary is just to select the particle size of the said glass bead suitably according to a use. A commercially available product may be used as the retroreflective layer (5). Moreover, you may utilize the commercial item which laminated | stacked the luminous layer (7) on the retroreflection layer (5).

  The luminous layer (7) in this invention is formed by printing under the said transparent base material layer (6). As a printing method, the phosphorescent layer (7) can be formed with phosphorescent ink by, for example, a screen printer. The phosphorescent ink is not particularly limited as long as it is a phosphorescent ink, but a phosphorescent ink containing strontium aluminate is preferable in terms of a long emission time.

Examples of the pressure-sensitive adhesive layer in the present invention include commonly used pressure-sensitive adhesives such as acrylic pressure-sensitive adhesives and natural rubber latex pressure-sensitive adhesives. A preferable example is an acrylic pressure-sensitive adhesive, which has strong adhesive force and strong cohesive force, and is preferable without stickiness. The application amount of the pressure-sensitive adhesive is preferably 50 to 300 g / m ² (when dried). As a laminating method, it can be easily laminated on the phosphorescent layer (7) surface of the retroreflective layer (5) by coating on one side or both sides of the aluminum sheet (8) in advance.

  The aluminum sheet (8) in the present invention is a sheet made of a metal such as aluminum or an aluminum alloy. By laminating the aluminum sheet (8) on the back surface of the phosphorescent retroreflective sheet (1), due to the flexibility of the aluminum sheet (8), a hammer, a roller, etc. It can be easily deformed along the unevenness on the floor and wall surface of the station platform, building entrance / exit, passage etc. by hitting or pressing from above with appropriate means In the work, the phosphorescent retroreflective sheet (1) can be applied with a strong adhesive force in a state of being in close contact with the floor surface or the wall surface. After construction, the phosphorescent retroreflective sheet (1) has high peel strength, and the aluminum sheet (8) has no shrinkage or corrosion, is excellent in dimensional stability, and can be easily applied to uneven surfaces. A durable phosphorescent retroreflective sheet (1) without any material can be obtained.

  The thickness of the aluminum sheet (8) is preferably 20 μm to 100 μm. If it is thinner than that, the strength will be insufficient, while if it is thicker than that, the conformity to the floor surface will be poor and sufficient peel strength will not be obtained.

  The tear strength in all layers of the luminous retroreflective sheet (1) after the aluminum sheet (8) is laminated needs to be 50 N / mm or more. If it is 50 N / mm or more, it has sufficient strength, and there is no problem that the phosphorescent retroreflective sheet (1) is torn or torn due to frequent walking.

  Moreover, the method of sticking the phosphorescent retroreflective sheet (1) of the present invention to the flooring may be performed by applying an adhesive to the flooring and pasting the phosphorescent retroreflective sheet (1). A method may be used in which an adhesive layer is coated on the surface of the aluminum sheet (8) and a release paper is pasted, and then the release paper is peeled off at the time of construction and attached to the flooring. Moreover, as an adhesive, the acrylic adhesive with strong adhesive force is preferable. Furthermore, the peel strength when the phosphorescent retroreflective sheet (1) of the present invention is adhered to a flooring is preferably 25 N / 25 mm or more.

Next, examples of the present invention will be described. The total light transmittance and peel strength were measured based on the following measurement methods.
<Measurement method of total light transmittance>
The total light transmittance was measured in accordance with JIS K 7361.
<Peel strength measurement method>
The peel strength was measured according to JIS A 5536.
<Example 1>
Polypropylene resin 59.8% by weight, SEBS (styrene / ethylene / butylene / styrene copolymer) resin 35% by weight (olefin-based thermoplastic elastomer-compatible resin), terpene resin (natural resin-based low molecular weight resin) ) 5% by weight was mixed, heated and melted to obtain a sheet of a surface protective layer having a thickness of 0.2 mm with a calender. A commercial product in which an acrylic film having a printed layer printed with “evacuation route” and a retroreflective layer were laminated via an acrylic adhesive layer, and a commercially available PET film in which a phosphorescent layer was laminated were prepared. Next, in another step, an acrylic pressure-sensitive adhesive layer was applied to both sides of an aluminum sheet having a thickness of 50 μm, and an aluminum sheet with an adhesive layer having a thickness of 200 μm in which a release paper was pasted on one side was obtained. Subsequently, an adhesive layer is applied to the lower side of the surface protective layer sheet, and laminated so that the surface protective layer, the printed layer, the acrylic film, the retroreflective layer, the PET film, and the phosphorescent layer are arranged in this order. The pressure-sensitive adhesive side of the sheet was laminated on the phosphorescent layer side and cut into the shape of the sheet to produce a phosphorescent retroreflective sheet. The thickness after lamination was 0.8 mm. The tear strength in all layers was 61 N / mm. The total light transmittance of the surface protective layer was 82%. Further, the peel strength was 32 N / 25 mm and the workability was good.

<Example 2>
A phosphorescent retroreflective sheet was obtained in the same manner as in Example 1 except that the thickness of the aluminum sheet was 30 μm. The tear strength in all layers after lamination was 55 N / mm. Further, the peel strength was 27 N / 25 mm and the workability was good.

<Example 3>
A phosphorescent retroreflective sheet was obtained in the same manner as in Example 1 except that the thickness of the aluminum sheet was 80 μm. The tear strength in all layers after lamination was 66 N / mm. Further, the peel strength was 33 N / 25 mm and the workability was good.

<Comparative Example 1>
In the same manner as in Example 1, a 0.2 mm-thick surface protective layer sheet was obtained. Next, 10 g / m ² (during drying) of maleic anhydride-modified polypropylene resin is applied to the lower surface of the surface protective layer sheet, dried, and then printed as an “evacuation route” with an ink jet printer to form a printed layer did. Next, in another step, an acrylic pressure-sensitive adhesive layer was applied to both sides of an aluminum sheet having a thickness of 50 μm, and an aluminum sheet with an adhesive layer having a thickness of 200 μm in which a release paper was pasted on one side was obtained. Subsequently, the printed layer side of the sheet of the surface protective layer and the aluminum sheet with the adhesive layer were laminated via an acrylic adhesive layer to obtain an anti-slip sheet. The lights were turned off at night and the guidance display was not visible. Furthermore, although the light of the flashlight was irradiated, although the “evacuation route” was visible, the visibility as high as retroreflection was not exhibited. The peel strength was 34 N / 25 mm, and the workability was good.

<Comparative example 2>
A phosphorescent retroreflective sheet was obtained in the same manner as in Example 1 except that the aluminum sheet was omitted. Further, the peel strength was 15 N / 25 mm, and the adhesion was poor and the workability was poor.

<Comparative Example 3>
A phosphorescent retroreflective sheet was obtained in the same manner as in Example 1 except that the thickness of the aluminum sheet was 5 μm. The tear strength in all layers after lamination was 45 N / mm. The aluminum sheet was broken, the peel strength was 20 N / 25 mm, the adhesion was poor, and the workability was insufficient.

<Comparative example 4>
A phosphorescent retroreflective sheet was obtained in the same manner as in Example 1 except that the thickness of the aluminum sheet was 150 μm. The tear strength in all layers after lamination was 68 N / mm. However, it was difficult to adjust to the floor surface, and the peel strength was 24 N / 25 mm, resulting in poor adhesion and insufficient workability.

It is typical sectional drawing which shows the phosphorescent retroreflection sheet which shows one Embodiment of this invention.

1 Phosphorescent retroreflective sheet 2 Surface protective layer
3 Print Layer 4 Transparent Base Layer 5 Retroreflective Layer 6 Transparent Base Layer 7 Phosphorescent Layer 8 Aluminum Sheet

Claims (3)

  In the sheet having the retroreflective layer, a phosphorescent layer is laminated on the lower surface side of the retroreflective layer via a transparent base material layer, and a surface protective layer is further laminated on the upper surface side of the retroreflective layer, and the retroreflective layer An aluminum sheet is laminated on the phosphorescent layer side of the layer through an adhesive layer, the total light transmittance of the surface protective layer is 80% or more, and in all the layers of the phosphorescent retroreflective sheet after the aluminum sheet is laminated A phosphorescent retroreflective sheet having a tear strength of 50 N / mm or more.   In a sheet having a retroreflective layer, a printed layer is laminated on the upper surface side of the retroreflective layer, and a phosphorescent layer is laminated on the lower surface side via a transparent base material layer, and surface protection is further provided on the printed layer side of the retroreflective layer. Laminating a layer, laminating an aluminum sheet via an adhesive layer on the phosphorescent layer side of the retroreflective layer, the total light transmittance of the surface protective layer is 80% or more, the layer after laminating the aluminum sheet A phosphorescent retroreflective sheet, wherein the tear strength in all layers of the phosphorescent retroreflective sheet is 50 N / mm or more.   The phosphorescent retroreflective sheet according to claim 1, wherein the aluminum sheet has a thickness of 20 μm to 100 μm.