JP2009186526A - Heterogeneous visual display structure, and its display method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide heterogeneous display structure which is recognized as a signboard, a sign, a direction board, etc. under a light source, displays guidance display, a message, etc. without power in the darkness due to power interruption or putting out light, and in which the displays do not interfere with each other, and by which two kinds of displays are achieved by one body. <P>SOLUTION: The heterogeneous display structure (1) is provided by: providing a visual display layer (A)(5) on the surface of a porous sheet on the front surface side; further providing a visual display layer (B)(6) on the whole rear surface of a fluoroscopic control object; constituting the visual display layer (B) of a light accumulation luminous material-containing part (6a) and a light accumulation luminous material-non-containing part (6b); and controlling color difference (ΔE) to be equal to or less than 10, in a fluoroscopic control object obtained by laminating a light transmissive plane base (2), and the porous sheet (3) on the surface side of the light transmissive plane base (2), or on both of the surface side and the rear surface side. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a signboard, a sign, and a guide plate. To describe the present invention in detail, in facilities used by a large number of people such as underground station buildings, underground malls, hotels, department stores, movie theaters, amusement facilities, public facilities, school buildings, etc., usually as signs, signs, information boards, etc. Although it is recognized, the present invention relates to a display structure having a function of switching and displaying information such as guidance guidance display and a message without power in the dark.

  In urban areas, the number of users is overwhelming, especially because the underground station buildings and underground shopping streets, and the connecting passages between the underground shopping streets and the underground shopping streets, are well developed. These underground communication passages and concourses have similar landscape features, so it is difficult to understand the road despite signs, signs, and signboards being installed throughout. Therefore, in the event of a sudden power outage accident, it is extremely difficult to move safely in the dark and reach the destination safely. In addition, the underground passage has a strong sense of blockage, and in the event of a power outage due to a large-scale disaster, people are rushing to the exit all at once, and there are concerns about the occurrence of simultaneous accidents and panics such as shogi defeat.

  Therefore, recently, evacuation guide plates using materials that store phosphorescent light in the dark have been provided everywhere on the floors of underground stations, communication passages, concourses, stairs, and other corners of walls. Since such evacuation guide plates and signs are recognized to be able to sufficiently transmit messages with simple phosphorescent display such as arrow marks and evacuation exit symbol marks, the nameplate size is mainstream. However, in the case of a nameplate-sized phosphorescent light emitting plate, there is a problem that the presence of the phosphorescent light emitting plate cannot be recognized in the shadow of the crowd in an emergency situation where crowds gather together at the exit. This applies not only to underground station buildings and underground malls, but also to installation in hotels, department stores, movie theaters, amusement facilities, public facilities, school buildings, etc.

  On the other hand, since the underground station building concourse and underground street passages are crowded, their walls, floors, etc. are used as effective advertising spaces, and various advertising signs are installed. If some of these advertising signs can fulfill the function of evacuation guidance in the event of a power outage, it is possible to construct a facility with further disaster prevention measures. Based on such a concept, when lighting is turned on, it is recognized as a signboard, a sign, a guide board, etc., but in the dark, it can be recognized as an evacuation guidance display board and a display board for messages, etc. A proposal has also been made that also serves as an evacuation guidance sign. For example, in JP-A No. 2004-163561 (Patent Document 1), the first image display layer having a phosphorescent material is sandwiched between a perforated sheet having a plurality of holes, and visible under a light source. There is a proposal for a display film in which a second image display layer is formed. However, in this film, the outline of the first image display is raised from the second image display side, and when viewed from a distance, There is an inconvenience of overlapping the second image display. In Table 2005-050600 (Patent Document 2), a first image display layer having a phosphorescent material with a half mirror film sandwiched as a light transmission limiting layer, and a second image visible under a light source. There is a proposal of a display film in which a display layer is formed, but it is necessary to completely hide the metallic luster of the half mirror film with the second image display layer, and there is a significant limitation in the selection of the design. Therefore, under a light source, it is recognized as a signboard, a sign, a guide plate, etc., but in the dark, it is a display structure that can display guidance guidance display, messages, etc. without power, particularly a signboard during normal times, When used for applications such as signs and guide boards, there has been no display structure that cannot be seen through the outline of a special display that appears during a power failure or extinguishment.

JP 2004-163561 A No. 2005-050600

  The present invention is a display structure that can be recognized as a signboard, a sign, a guide board, etc. under a light source, and can display a guidance guidance display, a message, etc. without power in the dark due to a power failure or extinction. In particular, when using applications such as signboards, signs, and signboards during normal times, the special display contours that are displayed at the time of a power failure or light extinction do not show through and interfere with each other. An attempt is made to provide a display structure.

  In order to solve the above-described problems, in the present invention, in the transparency control body in which the porous sheet is laminated on both the light-transmitting planar base material and the front surface side or both the front surface side and the back surface side, A visual display layer (A) is provided on the surface of the porous sheet, and a visual display layer (B) is provided on the entire back surface of the transparency control body. The visual display layer (B) includes a phosphorescent material-containing part and It is composed of a portion that does not contain a phosphorescent material, and in particular, by setting the color difference (ΔE) between the phosphorescent material-containing portion and the phosphorescent material-free portion to 10 or less, a signboard, a sign, a guide plate, etc. The present invention was completed by finding that a display structure capable of two types of display can be obtained with a single solid body, through which the outline of a special display that is manifested in the event of a power outage or light extinction is transparent and there is no interference in the appearance. I came to let you.

  That is, the heterogeneous display structure of the present invention is a transparency control body in which a porous sheet is laminated on both a light-transmitting flat base material and the surface side or both the front surface side and the back surface side. A visual display layer (A) is provided on the surface of the porous sheet, and a visual display layer (B) different from the visual display (A) is provided on the entire back surface of the transparency control body. The visual display layer (B) is composed of a phosphorescent material-containing portion and a phosphorescent material-free portion, and preferably has a color difference ΔE (JIS-Z-8729) of 10 or less. It is preferable that the light-transmitting planar base material is a synthetic resin plate having a thickness of 1 to 10 mm, and the light-transmitting planar base material further includes a fiber fabric as a core material, and a thermoplastic resin on one or more sides. It is preferable to be a sheet-like laminate having a layer Further, it is preferable that the porous sheet is a perforated sheet made of a thermoplastic resin, and the porous sheet further includes a coarse fabric made of warp and weft as a core material, and the warp and weft Preferably, the surface of the strip is a mesh-like sheet coated with a thermoplastic resin, and the visual display layer (A) is further formed by gravure printing, screen printing, ink jet printing, transfer printing, and a combination thereof. Furthermore, it is preferable that the phosphorescent material-containing part of the visual display layer (B) is formed by printing, painting, sticking a shaped article, sticking a cutting sheet, and a combination thereof. Further, the portion of the visual display layer (B) that does not contain the phosphorescent material contains printing, painting, pasting of a shaped article, pasting of a cutting sheet, and this. It is preferable that these are used in combination, and it is further preferable that a weather-resistant protective layer is provided on the entire surface of the porous sheet including the visual display layer (A).

  The display method of these different types of visual display structures of the present invention is a transparent control body in which a porous sheet is laminated on both a light-transmitting flat base material and the surface side or both the front side and the back side. The visual display layer (A) is provided on the surface of the porous sheet on the surface side, and the visual display layer (B) different from the visual display (A) is provided on the entire back surface of the transparency control body. The visual display layer (B) is composed of a phosphorescent material containing portion and a phosphorescent material non-containing portion, and the color difference ΔE (JIS-Z-8729) is 10 or less. In this case, it is preferable that the luminous display by the phosphorescent material-containing part is transmitted through the hole of the porous sheet and the visual display layer (B) is luminescently displayed in dots.

  According to the present invention, one of the visual display layers formed on the visual display layer (A) and the visual display layer (B) is displayed on the outside according to a change in the situation at daytime or during lighting and at night or when the light is turned off. It is possible to provide a heterogeneous visual display structure that can be produced, and when using a signboard, a sign, a guide plate, etc. during normal times, the visual display layer (A) is not affected by the visual display layer (B). ) Can be clearly displayed, so that the heterogeneous visual display structure of the present invention can be used as signboards, signs, information boards, etc., such as underground station buildings, underground malls, hotels, department stores, movie theaters, play facilities, public facilities, school buildings, etc. It is possible to display guidance guidance messages and messages in the event of a power failure.

The heterogeneous visual display structure of the present invention is a see-through control body in which a porous sheet is laminated on the front surface side of the light-transmitting flat base material or both the front surface side and the back surface side. Are provided with a visual display layer (A), and further, a visual display layer (B) different from the visual display (A) is provided on the entire back surface of the transparency control body. The phosphorescent material containing part and the phosphorescent material non-containing part are made to have a color difference ΔE (JIS-Z-8729) of 10 or less. The light-transmitting flat base material used in the present invention is preferably a synthetic resin plate having a thickness of 1 to 10 mm, particularly 3 to 6 mm, and the light-transmitting flat base material is provided with a visual display layer (A). By providing it between the porous sheet and the visual display layer (B), the problem of appearance interference that the outline of the visual display layer (B) appears on the porous sheet side with the visual display layer (A) originally, Due to the photorefractive effect of the light-transmitting planar base material, it is possible to effectively suppress the phenomenon that the outline of the visual display layer (B) appears even when viewed from any angle. These synthetic as the resin acrylic resin, polycarbonate resin, polystyrene resin, polyester resin (PET resin), a vinyl ester resin, a thermoplastic resin such as semi-hard polyvinyl chloride resin, the refractive index 1.4 to 1.6 N _d A transparent resin having (JIS K7105) is most preferable, but a translucent emulsion or one obtained by blending light diffusing fine particles with a transparent resin can also be used. In the present invention, an acrylic resin (methacrylate resin) plate and a polycarbonate resin are most preferable. If the thickness of the light-transmitting planar base material is less than 1 mm, the phenomenon in which the outline of the visual display layer (B) appears to protrude toward the visual display layer (A) may not be effectively suppressed. On the other hand, if the thickness exceeds 10 mm, the obtained heterogeneous visual display structure may be unnecessarily heavy and difficult to construct and install.

  Moreover, as a light-transmitting planar base material, the sheet-like laminated body which contains a fiber fabric as a core material and has a thermoplastic resin layer on the single side | surface or more may be sufficient. Specifically, this sheet-like laminate has a fiber fabric such as a fiber woven fabric, a fiber knitted fabric, and a nonwoven fabric as a core material, and a soft polyvinyl chloride resin, a polyethylene resin, an ethylene-vinyl acetate copolymer on one side or both sides thereof. Light transmissive film or sheet obtained from one or more thermoplastic resins selected from resins, polypropylene resins, polyolefin elastomers, polyester elastomers, styrene elastomers, polyurethane elastomers, and fluorine copolymer resins Are laminated. The film (sheet) thickness of these thermoplastic resins is 0.1 to 2.0 mm, preferably 0.2 to 1.0 mm. As the fiber fabric, monofilament yarn such as polyester fiber (polyethylene terephthalate fiber), polypropylene fiber, nylon fiber, vinylon fiber, glass fiber, or multifilament yarn can be used, and these yarns are 250 to 1000 denier. A woven fabric or a knitted fabric having a coarse texture, a void, a non-void texture, obtained by entanglement of these yarns. The most preferable example in the present invention is a polyester (polyethylene terephthalate) fiber woven fabric (open stitch plain weave) as a core material, and a soft polyvinyl chloride resin film (sheet) having a thickness of 0.2 to 0.5 mm on both sides as an adhesive, Alternatively, a tarpaulin film material having a thickness of 0.5 to 2.0 mm laminated by means of thermal lamination can be used. To this soft polyvinyl chloride resin sheet, known PVC compounding agents such as pigments, stabilizers, fillers, flame retardants, weathering stabilizers and the like can be optionally added within a range that does not extremely impair light transmission. it can. The light transmittance of these light-transmitting planar substrates is 25 to 90%, preferably 50 to 75%, according to JIS standard Z8722 test method. If the light transmittance is less than 25%, the guidance display or message that appears under dark conditions may become unclear.

  The porous sheet used in the heterogeneous visual display structure of the present invention is a single thermoplastic resin film such as polyester resin, acrylic resin, polyurethane resin, polyamide resin, polystyrene resin, polyvinyl chloride resin, polyethylene resin, polypropylene resin, and fluorine resin. A multilayer sheet composed of a plurality of thermoplastic resin films (for example, a PET film as a polyester film) is preferable. The perforated sheet is composed of a perforated part and a non-perforated part, and the non-perforated part preferably has a light shielding property, and the light shielding means includes coloring hiding by adding an inorganic pigment such as titanium dioxide or carbon black. In the invention, the surface of the porous sheet is preferably colored with at least a white pigment such as titanium dioxide from the viewpoint of printing on the surface (visual display 1). In order to increase the light blocking property, it is preferable to print the back surface of the sheet with a carbon black-containing ink or a metal powder-containing ink such as aluminum to form a concealing layer. Moreover, in the said multilayer sheet, the sheet | seat etc. which made the surface layer white-colored, and made the back surface layer or the intermediate | middle layer the carbon black color, or made the concealment layer by coloring metal powders, such as aluminum, etc. can be used.

  Further, these porous sheets are perforated with a thickness of 0.05 to 1 mm, preferably 0.1 to 0.3 mm, in which a large number of holes are perforated by a known method such as punching at a uniform density number per unit area. The sheet has a hole diameter of 0.5 to 5.0 mmφ, preferably 1 to 2.5 mmφ. If the hole diameter is less than 0.5 mmφ, the luminous intensity of the visual display layer (B) may be insufficient in the resulting display structure, and if the hole diameter exceeds 5.0 mmφ, The visibility of the visual display layer (A) may be insufficient. Moreover, the perforation degree of a porous sheet is 0.2-0.6, Most preferably, it is 0.3-0.5. The degree of perforation is the ratio of the total area of perforations contained in the unit area to the unit area of the perforated sheet. The indication obtained when the degree of perforation is less than 0.2 (total area of perforations is less than 20%) In the structure, the luminous intensity of the visual display layer (B) may be insufficient, and when the perforation degree exceeds 0.6 (the total area of perforations exceeds 60%), the resulting display structure The visibility of the visual display layer (A) may be insufficient. The shape of the perforation includes a geometric form such as a circle, an ellipse, a quadrangle, and a hexagon, and an irregular form in which these geometric forms are broken.

  Further, as the porous sheet, a mesh-like sheet obtained by including a warp and a coarse fabric composed of wefts as a core material and coating the surfaces of the warp and wefts with a thermoplastic resin can be used. This mesh sheet is specifically a woven fabric or a knitted fabric. In particular, a coarse fabric having a gap between the yarns and the yarn is used as a core material, and the entire surface of the yarn included in the coarse fabric is softened with a soft poly. One or more thermoplastics selected from vinyl chloride resin, acrylic resin, polyethylene resin, ethylene-vinyl acetate copolymer resin, polypropylene resin, ionomer resin, polyester resin, polyurethane resin, fluororesin, and these copolymer resins It is coated with resin. These thermoplastic resin coatings may be 20 to 100 wt% with respect to the mass per unit area of the coarse fabric, and a part thereof may be impregnated into the fiber yarn. As the coarse fabric, monofilament yarn such as polyester fiber, polypropylene fiber, nylon fiber, vinylon fiber, glass fiber, or multifilament yarn can be used. These yarns are 100 to 1000 denier, preferably 250 to 750. A coarse woven or knitted fabric which is denier and is obtained by entanglement of these yarns. The most preferable example in the present invention was obtained by coating a coarsely woven plain fabric made of polyester fibers, particularly black dyed polyester fibers, and coating a soft compounded polyvinyl chloride resin paste or by dipping (impregnation). A mesh sheet can be used.

  The mesh sheet is composed of an open portion and a non-open portion, and the non-open portion preferably has a light blocking property by a thermoplastic resin coating, and an inorganic pigment such as titanium dioxide or carbon black is added as a light blocking means. In the present invention, the surface of the mesh sheet (porous sheet) is preferably colored with at least a white pigment such as titanium dioxide from the viewpoint of printing on the surface (visual display 1). . In order to increase the light blocking property, it is preferable to print the back surface of the sheet with a carbon black-containing ink or a metal powder-containing ink such as aluminum to form a concealing layer. The mesh sheet may be a two-layered thermoplastic resin coating in which the surface layer is white-colored and the underlayer is carbon black-colored or a metal powder such as aluminum is masked. Moreover, the aperture part of these mesh-like sheets (perforated sheet) is an aperture sheet having a thickness of 0.05 to 1 mm, preferably 0.1 to 0.3 mm, and the pore size is 0.5 to 5 mm. 0.0 mm, preferably 1 to 2.5 mm. If the pore size is less than 0.5 mm, the amount of stored light emission of the visual display layer (B) may be insufficient in the resulting display structure, and if the pore size exceeds 5.0 mm, the resulting display structure The clearness of the visual display layer (A) may be insufficient in the body. The openness of the mesh sheet is 0.20 to 0.6, particularly preferably 0.3 to 0.5. The degree of opening is the ratio of the total area of the holes included in the unit area to the unit area of the mesh sheet, and the degree of opening is less than 0.2 (the total area of the holes is less than 20%). In the obtained display structure, the luminous intensity of the visual display layer (B) may be insufficient, and the degree of opening exceeds 0.6 (the total area of the perforations exceeds 60%). In some display structures, the visibility of the visual display layer (A) may be insufficient. The shape of the opening is a square, a rectangle, a rhombus, or a deformed body with rounded corners.

  In the heterogeneous visual display structure of the present invention, the visual display layer (A) is not particularly limited in display contents such as paintings, illustrations, photographs, and characters, and these are any of gravure printing, screen printing, inkjet printing, and transfer printing. However, inkjet printing based on the output of computer processed image data is particularly suitable. The heterogeneous visual display structure of the present invention is provided with a visual display layer (A) on the surface of a porous sheet (mesh sheet) in advance, and the porous sheet (mesh sheet) provided with the visual display layer (A) It is laminated on the surface of a transparent flat substrate. Moreover, in this invention, this porous sheet (mesh-like sheet) can be laminated | stacked and used for the surface of a light-transmitting planar base material, and a back surface. In this case, it is preferable that it is black type | system | group colors, such as black-dark gray, only for the porous sheet (mesh-like sheet | seat) laminated | stacked on the light transmissive planar base material back surface side. When two layers of porous sheets are arbitrarily laminated with a light-transmitting planar substrate interposed therebetween, the overlapping of the upper and lower perforated (perforated) portions is shifted randomly, resulting in perforation (perforated) of the visual display layer (A). ) Part of the non-perforated part (non-perforated part) of black color such as black to dark gray on the back surface perforated sheet (mesh-like sheet) appears to protrude, which is the perforated part of the visual display layer (A) As a result of the bordering effect of the (opening portion), the display of paintings, illustrations, photographs, characters, etc. can be more clearly enhanced. Lamination of the porous sheet (mesh-like sheet) with the visual display layer (A) and the light-transmitting planar base material can be performed by using a known adhesive, but the visual display layer (A) is periodically formed. When it is necessary to replace the layer with another visual display layer, it is preferable to use an adhesive that can be easily separated, fixing with an adhesive tape, fixing with male and female uneven members such as velcro, clip fixing, screw fixing, and the like.

In the heterogeneous visual display structure of the present invention, the visual display layer (B) is formed by the phosphorescent material containing portion and the phosphorescent material non-containing portion, and particularly the phosphorescent material containing portion and the phosphorescent material. The color difference ΔE (JIS-Z-8729) from the non-luminescent material-containing part is 10 or less, preferably 6 or less. If the color difference ΔE exceeds 10, the visual display layer (B) on the back surface may be visually observed from the side surface of the visual display layer (A), which may interfere with the appearance and hinder the visual display layer (A). There is. In order to make the color difference ΔE 10 or less, for example, if the color of the phosphorescent material-containing portion is blue-green, it is preferable that the phosphorescent material-free portion is also toned and adjusted to be blue-green. As the phosphorescent material, known phosphorescent phosphors (phosphorescent pigments / luminous pigments), and green phosphorescent color type particles and blue phosphorescent color type particles can be used. As a blue phosphorescent color type, 0.001 to 10 mol% of a divalent metal aluminate (for example, strontium aluminate) base crystal was added to a divalent metal using a rare earth element as an activator. Particles. Divalent metals include magnesium, calcium, strontium, barium, zinc, and rare earth elements include cerium, praseodymium, neodymium, samarium, europium, gadolinium, terbium, dysprosium, holmium, erbium, thulium, ytterbium, lutetium, etc. , and the _{specifically, SrAl 2 O 4: Eu,} Dy, Sr 4 Al 14 O 25: Eu, Dy, CaAl 2 O 4: Eu, Nd, SrAl 14 B 14 O 25: Eu, illustrate Dy or the like In particular, phosphorescent phosphor particles based on alumina strontium oxide (SrAl ₂ O ₄ : Eu, Dy) are preferable. Further, calcium sulfide / bismuth system [CaS: Bi (purple blue light emission)], calcium sulfide / strontium / bismuth system [CaSrS: Bi (blue light emission)], zinc sulfide / copper system [ZnS: Cu (green light emission)], Sulfide-based phosphorescent phosphors such as zinc sulfide / cadmium / copper-based [ZnCdS: Cu (yellow to orange light emission)] can also be used.

  The phosphorescent material-containing part is formed by printing, painting, sticking a shaped article, sticking a cutting sheet, and a combination thereof. Specifically, these include screen printing, gravure printing using a paint containing a phosphorescent material, in particular, a paint in which phosphorescent material particles are uniformly dispersed in a transparent to emulsion-based synthetic resin solution. Also, spray coating and brush coating using these paints are possible, and UV curing treatment can be performed by using an ultraviolet curable resin for these printing and coating. Further, in a molded product obtained by processing a composition in which phosphorescent material particles are uniformly dispersed in a transparent to emulsion-based synthetic resin, for example, a thermoplastic resin composition such as a soft polyvinyl chloride resin. Phosphorescent material particles are kneaded uniformly, processed into a sheet of a certain thickness, and then pasted into an arbitrary shape, and phosphorescent is stored in a thermoplastic resin composition such as pasty polyvinyl chloride resin. Affixed with a molded product obtained by solidifying a liquid in which luminescent material particles are uniformly dispersed in a mold of any shape, and the cutting sheet is made of a heat-resistant material such as pasty polyvinyl chloride resin. A liquid in which phosphorescent material particles are uniformly dispersed in a plastic resin composition is processed into a sheet having a thickness of 0.1 to 0.5 mm, and a transparent color adhesive is applied thereto. The amount of the phosphorescent material contained in the phosphorescent material-containing part is 20 to 60% by mass, and the concentration of the phosphorescent material amount contained in the unit area is determined according to the thickness setting of the phosphorescent material-containing part. What is necessary is just to adjust to a high density | concentration with respect to a thin film | membrane, and a slightly low density | concentration with respect to a thick film | membrane. Further, the phosphorescent material-free part is a phosphorescent material in any of the materials for printing, coating, molding, and cutting sheet used for forming the phosphorescent material-containing part. The color difference ΔE from the phosphorescent material-containing part is adjusted and adjusted to 10 or less. When more than half of the visual display layer (B) is the phosphorescent material-containing part, the entire surface of the visual display layer (B) is formed with the phosphorescent material-containing part, and only the part that does not emit phosphorescent light is phosphorescent. It may be covered with a material-free material and concealed. Conversely, when the area of the phosphorescent material containing portion of the visual display layer (B) is less than half, the entire surface of the visual display layer (B) is covered. You may coat | cover only the part formed with a luminous light emission material non-contained part and carrying out the luminous light emission with the luminous light emission material containing material.

  In the heterogeneous visual display structure of the present invention, it is preferable that a weather-resistant protective layer is provided on the entire surface of the porous sheet including the visual display layer (A). The weather-resistant protective layer is an effect that attaches to the dissimilar visual display structure of the present invention the effect of suppressing the fading of the visual display layer (A) and the effect of suppressing the adhesion of dust and dirt on the visual display layer (A). The weather-resistant protective layer is formed by laminating a transparent coating film or a transparent film. In order to improve the fading suppression effect of the visual display layer (A), a transparent coating film and a transparent film have a benzophenone ultraviolet absorber, a benzotriazole ultraviolet absorber, and a cyanoacrylate ultraviolet absorber. In addition, it contains at least a known ultraviolet absorber such as an agent, and can be used in combination with a known hindered amine-based light stabilizer, and a known antioxidant can be used as required. 0.05-5 mass% is suitable. Specifically, the weather-resistant protective layer includes acrylic resin, acrylic-silicone copolymer resin, acrylic-fluorine copolymer resin, fluorine-based copolymer resin, vinylidene fluoride resin, acrylic-urethane copolymer resin, and cross-linked urethane. A transparent coating film having a thickness of 0.001 to 0.1 mm obtained by applying and drying a solution containing one or more kinds of resin dissolved therein, or one or more kinds of these resins are melted and molded, It is a single-layer transparent film having a thickness of 0.01 to 0.5 mm, or a multilayered transparent film. In addition, a thin film made of one or more selected from fine particle silica (particularly colloidal silica), photocatalytic substance (particularly titanium dioxide), and organic silicate compound (hydrolyzed condensate of methyl or ethyl silicate) is formed on the surface of the weather protection layer. By doing so, it is possible to obtain a display structure having further excellent antifouling properties.

Hereinafter, the heterogeneous visual display structure of the present invention will be described in detail.
FIG. 1 is a view showing a state of a different type visual display structure of the present invention under a light source, and a visual display layer (A) (5) of a star-shaped (pentagonal) mark is provided on the surface of a porous sheet (3). , Gravure printing, screen printing, ink jet printing, transfer printing, etc., and the porous sheet (3) is a perforated sheet (3a) made of a thermoplastic resin having perforations (3b), or perforated ( Any of the mesh-like sheets (3c) having 3d). These perforations (3b) and apertures (3d) are partially missing prints for displaying part of the star-shaped (pentagonal) mark configuration of the visual display layers (A) and (5). In this state, it is a part of the visual display layer (B) that is displayed in the perforated (3b) part and the perforated (3d) part and is observed in the form of dots.

  FIG. 2 shows the state of the heterogeneous visual display structure (FIG. 1) of the present invention under no light source (when power is interrupted or extinguished), and the surface of the porous sheet (3) is star-shaped with no light source. The visual display layers (A) and (5) of the (pentagonal) mark are not observed. It is a part of the visual display layer (B) that is displayed on the perforated (3b) part or the perforated (3d) part of the porous sheet (3) and is observed in the form of dots. The visual display layer (B) includes a phosphorescent material-containing portion (6a) and a phosphorescent material-free portion (6b), and the phosphorescent material-free portion (6b) is a star (hexagonal star). A mark is formed, and the margin is formed by the phosphorescent material containing portion (6a). FIG. 2 shows a star-shaped (hexagonal star) mark as a dark part by phosphorescent emission of the observed phosphorescent material displayed in the perforated (3b) or open (3d) part. It is a figure showing performing the shadow display to perform.

  FIG. 3 shows an example of a specific configuration of the heterogeneous visual display structure (1) of the present invention. One layer of porous sheet (3) has a transparent control body (4) structure laminated on the surface side of the light-transmitting planar base material (2). It is a figure which shows that the display layers (A) and (5) are formed, and the visual display layers (B) and (6) are further formed on the back side of the structure of the transparency control body (4). The light transmissive planar substrate (2) is either a synthetic resin plate (2a) or a sheet-like laminate (2b), and the porous sheet (3) is a perforated sheet (3a) made of a thermoplastic resin. ) Or mesh sheet (3c).

  FIG. 4 further shows an example of a specific configuration of the heterogeneous visual display structure (1) of the present invention. A two-layer porous sheet (3) is formed on the surface side and the back side of the light-transmitting planar base material (2) to form a transparent control body (4) structure, and the surface side porous sheet The visual display layers (A) and (5) are formed on (3), and the visual display layers (B) and (6) are formed on the porous sheet (3) on the back surface side of the transparent control body (4) structure. It is a figure which shows being done. The light transmissive planar substrate (2) is either a synthetic resin plate (2a) or a sheet-like laminate (2b), and the two porous sheets (3) are perforated made of a thermoplastic resin. One or more selected from the sheet (3a) and the mesh sheet (3c).

1). A white PET / polyethylene terephthalate (0.05 mm thick) layer colored with a white pigment and a black PET (polyethylene terephthalate) 0.05 mm thick layer colored with a black pigment. A perforated sheet having a perforation degree of 34, in which a large number of circular holes having a diameter of 2 mmφ were punched at equal intervals on a black two-tone film, was used. (The perforation degree is the ratio of the perforated sheet unit area to the total area of perforations contained in the unit area.) An ink jet printer using a solvent-based ink is used on the white PET surface of the perforated sheet. Blue star mark (2 cm pentagon), red star mark (2 cm pentagon), and yellow star mark (2 cm pentagon) are drawn alternately. A visual display layer (A) was formed.
2). A five-point star is formed on the back side of a transparent acrylic flat plate (light-transmitting flat base material) having a uniform thickness of 5 mm and a refractive index of 1.49 n _d (JIS K7105) by containing no phosphorescent material. A star-shaped mark (hexagon) larger than the mold was printed and formed as a phosphorescent material-free portion. Next, the phosphorescent material-containing portion was printed and formed on the entire back surface of the acrylic flat plate (light-transmissive flat base material) by screen printing containing the phosphorescent material. When this is observed from the surface of the acrylic flat plate, a visual display layer (B) in which all of the periphery of the star-shaped mark (hexagon of 3 cm on each side) not containing the phosphorescent material is a phosphorescent material-containing portion, The color difference ΔE (JIS-Z-8729) between the luminescent material-containing portion and the non-luminescent material-containing material-containing portion was 2.3.
<Ink containing no phosphorescent material>
Tones of pastel green (melon color) blended with 5% standard color green and 1.5% standard color yellow based on the standard white color of UV-curable screen ink HUG (epoxy acrylate) made by Seiko Advance The composition was used.
<Ink containing phosphorescent material>
Based on the standard clear color of UV curable screen ink HUG (epoxy acrylate type) manufactured by Seiko Advance Co., Ltd. Light-emitting luminescent material manufactured by Easy Bright Co., Ltd .: Part No. EZCB-50E (Sr ₄ Al ₁₄ O ₂₅ : EU, Dy) The composition which mix | blended 40 mass% with respect to ink solid content was used.
3). Next, of the porous sheet with the visual display layer (A) obtained in 1), an acrylic adhesive was gravure-coated on the black PET surface, and the visual display layer (B) was provided on the back surface obtained in 2). The laminate was laminated on the surface of an acrylic flat plate (light transmissive flat substrate). Furthermore, a vinylidene fluoride transparent film having a thickness of 50 μm is laminated on the entire surface of the porous sheet with the visual display layer (A) using an adhesive (containing an ultraviolet absorber) to form a visual display layer (A) and a visual display layer ( A display body having a size of 65 cm in the vertical direction and 95 cm in the horizontal direction was obtained.
4). The display body obtained in 3) was hung on the wall in the dark room with the visual display layer (B) as the back, and the display body was displayed using a light source lamp having a wavelength in the ultraviolet region. At this time, the pattern of the blue star mark (pentagon), red star mark (pentagon), and yellow star mark (pentagon) drawn on the visual display layer (A) is vivid. The pattern interference on the appearance of the visual display layer (A) due to the pattern of the visual display layer (B) was not recognized.
5). When the visual display layer (A) is displayed in the state of 4) and the light source irradiation is stopped after 1 hour, the interior becomes completely dark and the visual display layer (A) is completely invisible. Suddenly at the position where the layer (A) was displayed, a large number of hexagonal star marks each having a side of 3 cm, which was the pattern of the visual display layer (B), were displayed. This visual display layer (B) was transmitted through the hole of the porous sheet, displayed in the form of dots by yellow-green phosphorescence, and displayed in a star shape by dark portions that did not emit phosphorescence.

1). The visual display layer (A) and the visual display layer were the same as in Example 1 except that the porous sheet (white / black two-tone perforated sheet) of Example 1 was changed to the mesh sheet shown in 2) below. A display body comprising (B) and having a size of 65 cm in the vertical direction and 95 cm in the horizontal direction was obtained. In this display, there was no design interference on the appearance of the visual display layer (A) due to the pattern of the visual display layer (B). The display was displayed on the visual display layer (A) using a light source lamp having a wavelength in the ultraviolet region in the same manner as in Example 1, and when the light source irradiation was stopped after 1 hour, the room was completely dark. Thus, the visual display layer (A) was completely invisible, and suddenly the pattern of the visual display layer (B) appeared and displayed at the position where the visual display layer (A) was displayed. This visual display layer (B) was transmitted through the apertures of the mesh sheet, displayed as dots with yellow-green phosphorescence, and displayed with a star shape with dark portions that did not emit phosphorescence.
2). <Mesh sheet>
Black dyed polyester fiber multifilament yarn (250 denier) is used as warp and weft, and a plain fabric with a warp yarn and weft insertion of 25/1 inch is used as the base fabric. A white paste-like polyvinyl chloride resin composition (paste PVC, phthalic acid plasticizer, barium composite metal stabilizer, calcium carbonate filler, titanium dioxide white pigment, etc. can be widely used. ) And heated to be gelled, thereby obtaining a mesh sheet (mass 130 g / m ² ) having a porosity of 30 and colored in white and coated on the surface with resin. Each of the openings is a square with a side of 0.7 mm in size, and the distribution of the openings included per 1 inch length of the mesh sheet is 24 each.

1). The visual display layer (A) and the visual display layer are the same as in Example 1 except that the acrylic flat plate (light-transmitting flat base material) of Example 1 is changed to the sheet-like laminate shown in 2) below. A display body comprising (B) and having a size of 65 cm in the vertical direction and 95 cm in the horizontal direction was obtained. In this display, there was no design interference on the appearance of the visual display layer (A) due to the pattern of the visual display layer (B). The display was displayed on the visual display layer (A) using a light source lamp having a wavelength in the ultraviolet region in the same manner as in Example 1, and when the light source irradiation was stopped after 1 hour, the room was completely dark. Thus, the visual display layer (A) was completely invisible, and suddenly the pattern of the visual display layer (B) appeared and displayed at the position where the visual display layer (A) was displayed. This visual display layer (B) was transmitted through the hole of the porous sheet, displayed in the form of dots by yellow-green phosphorescence, and displayed in a star shape by dark portions that did not emit phosphorescence.
2). <Sheet laminate>
Polyester fiber multifilament yarn (420 denier) is used as warp yarn and weft yarn, and a warp yarn and a Raschel woven fabric in which the number of driven weft yarns is 18/1 inch is used as a base fabric, and both sides of the base fabric are used. , 0.15 mm thick polyvinyl chloride resin composition film (a wide range of known formulations comprising straight PVC, phthalic plasticizer, barium composite metal stabilizer, calcium carbonate filler, titanium dioxide white pigment, etc.) To obtain a light-transmitting sheet-like laminate having a thickness of 0.35 mm.

The visual display layer (A) and the visual display layer were the same as in Example 1 except that the porous sheet (white / black two-tone perforated sheet) used in Example 3 was changed to the mesh sheet used in Example 2. A display body having a display layer (B) size of 65 cm in the vertical direction and 95 cm in the horizontal direction was obtained. In this display, there was no design interference on the appearance of the visual display layer (A) due to the pattern of the visual display layer (B). The display was displayed on the visual display layer (A) using a light source lamp having a wavelength in the ultraviolet region in the same manner as in Example 1, and when the light source irradiation was stopped after 1 hour, the room was completely dark. Thus, the visual display layer (A) was completely invisible, and suddenly the pattern of the visual display layer (B) appeared and displayed at the position where the visual display layer (A) was displayed. This visual display layer (B) was transmitted through the apertures of the mesh sheet, displayed as dots with yellow-green phosphorescence, and displayed with a star shape with dark portions that did not emit phosphorescence.

In the display body of Example 1, one layer of a porous sheet made of the same white / black two-tone film as in Example 1 was added between the back surface of the acrylic flat plate (light-transmitting flat base material) and the visual display layer (B). And it laminated | stacked with the black PET surface facing the back surface side of the acrylic flat plate (light-transmissive flat base material). Except this, it carried out similarly to Example 1, and obtained the display body of the vertical direction 65cm x horizontal direction 95cm size which comprises the visual display layer (A) and the visual display layer (B). In this display body, by adding one black porous sheet, the design of the visual display layer (A) looks clearer, and the visual display layer (A) appearance by the pattern of the visual display layer (B) No symbolic interference was observed. The display was displayed on the visual display layer (A) using a light source lamp having a wavelength in the ultraviolet region in the same manner as in Example 1, and when the light source irradiation was stopped after 1 hour, the room was completely dark. Thus, the visual display layer (A) was completely invisible, and suddenly the pattern of the visual display layer (B) appeared and displayed at the position where the visual display layer (A) was displayed. This visual display layer (B) passes through the holes of the two layers of porous sheets interposed between the front and back of the acrylic flat plate and is displayed in the form of dots by yellow-green phosphorescence, and the star-shaped shape is displayed by dark portions that do not emit phosphorescence. It was what was done.

In the display body of Example 2, between the back surface of the acrylic flat plate (light-transmitting flat base material) and the visual display layer (B), a mesh-like sheet having the same standard as Example 2 was used, but colored black. One layer was added. Other than that was carried out similarly to Example 2, and obtained the display body of the vertical direction 65cm x horizontal direction 95cm size which comprises the visual display layer (A) and the visual display layer (B). In this display, by adding one black mesh sheet (porous sheet), the design of the visual display layer (A) looks clearer, and the visual display is based on the pattern of the visual display layer (B). No pattern interference with the layer (A) appearance was observed. The display was displayed on the visual display layer (A) using a light source lamp having a wavelength in the ultraviolet region in the same manner as in Example 1, and when the light source irradiation was stopped after 1 hour, the room was completely dark. Thus, the visual display layer (A) was completely invisible, and suddenly the pattern of the visual display layer (B) appeared and displayed at the position where the visual display layer (A) was displayed. This visual display layer (B) passes through the holes of the two-layer mesh sheet (porous sheet) interposed between the front and back of the acrylic flat plate and is displayed as dots by yellow-green phosphorescence, and is displayed by dark portions that do not emit phosphorescence. The star shape was displayed.

In the display body of Example 3, one porous sheet made of the same white / black two-tone film as in Example 1 was added between the back surface of the sheet-like laminate and the visual display layer (B), and the sheet-like lamination was performed. Lamination was performed with the black PET surface facing the back side of the body. Other than that was carried out similarly to Example 1, and obtained the display body of the vertical direction 65cm x horizontal direction 95cm size which comprises the visual display layer (A) and the visual display layer (B). In this display body, by adding one black porous sheet, the design of the visual display layer (A) looks clearer, and the visual display layer (A) appearance by the pattern of the visual display layer (B) No symbolic interference was observed. The display was displayed on the visual display layer (A) using a light source lamp having a wavelength in the ultraviolet region in the same manner as in Example 1, and when the light source irradiation was stopped after 1 hour, the room was completely dark. Thus, the visual display layer (A) was completely invisible, and suddenly the pattern of the visual display layer (B) appeared and displayed at the position where the visual display layer (A) was displayed. This visual display layer (B) is transmitted through the holes of the two layers of porous sheets interposed between the front and back of the sheet-like laminate, and is displayed as dots by yellow-green phosphorescence, and is star-shaped by dark portions that do not emit phosphorescence. The shape was displayed.

In the display body of Example 4, one layer is added between the back surface of the sheet-like laminate and the visual display layer (B), which is a mesh sheet of the same standard as in Example 2, but colored black. did. Other than that was carried out similarly to Example 1, and obtained the display body of the vertical direction 65cm x horizontal direction 95cm size which comprises the visual display layer (A) and the visual display layer (B). In this display body, the design of the visual display layer (A) is made clearer by adding one black mesh sheet, and the visual display layer (A) by the pattern of the visual display layer (B). There was no pattern interference with the appearance. The display of the visual display layer (A) was performed using a light source lamp having a wavelength in the ultraviolet region in the same manner as described above, and when the light source irradiation was stopped after 1 hour, the room became completely dark and the visual display layer (A) The pattern of the visual display layer (B) suddenly appeared and displayed at the position where the visual display layer (A) was displayed until now. This visual display layer (B) is transmitted through the apertures of the two-layer mesh sheet interposed between the front and back sides of the sheet-like laminate, and is displayed as dots by yellow-green phosphorescence, and by dark portions that do not emit phosphorescence. The star shape was displayed.

Comparative Example 1

In the visual display layer (B) of Example 1, printing of the phosphorescent material-free portion was omitted, and only the phosphorescent material-containing portion was used, and this was the same as Example 1. The color difference ΔE (JIS-Z-8729) between the acrylic flat plate (light-transmitting flat base material) and the phosphorescent material-containing part was 26.6. In this display body, by omitting the printing of the phosphorescent material-free portion, the design of the visual display layer (A) causes the design interference due to the pattern of the visual display layer (B), and the visual display layer (A) The appearance impression was bad.

Comparative Example 2

In the visual display layer (B) of Example 1, the ink of the portion not containing the luminous material is a standard color red 20 based on the standard white color of the UV curable screen ink HUG (epoxy acrylate type) manufactured by Seiko Advance. % And the same composition as Example 1 except that the ink composition was changed to pink. The color difference ΔE (JIS-Z-8729) between the phosphorescent material-free portion and the phosphorescent material-containing portion was 14.8. In this display body, when the color difference ΔE between the phosphorescent material-free portion and the phosphorescent material-containing portion exceeds 10, the pattern of the visual display layer (B) is changed to the pattern of the visual display layer (A). As a result, the appearance of the visual display layer (A) was poor.

Comparative Example 3

In the display body of Example 1, the lamination direction of the light-transmitting planar base material (acrylic flat plate) with the visual display layer (B) was reversed, and the visual display layer (A) / porous sheet / visual display layer (B) / It was set as the structure of the light-transmissive planar base material (acrylic flat plate). In this display body, the visual display layer (B) is formed on the design of the visual display layer (A) by reversing the lamination direction of the light-transmitting planar base material (acrylic flat plate) with the visual display layer (B). The pattern interference due to the pattern resulted in a poor appearance appearance of the visual display layer (A).

As apparent from Examples 1 to 8 and Comparative Examples 1 to 3, the heterogeneous visual display structure of the present invention has a visual display layer (in accordance with a change in the situation during daytime or lighting, and at night or when extinguished. It is possible to provide a special display structure in which any one of the visual display layers formed on A) and the visual display layer (B) can be exposed to the outside. Since the visual display layer (A) can be clearly and clearly displayed without being affected by the visual display layer (B) when used for applications such as the above, the heterogeneous visual display structure of the present invention can be used as a signboard, a sign, If it is applied to facilities such as underground station buildings, underground malls, hotels, department stores, movie theaters, amusement facilities, public facilities, school buildings, etc. as guide boards, guidance guidance displays and messages can be displayed immediately in the event of an unexpected power outage Yes, for safety and security measures It is extremely useful.

The figure which shows the observation state under the light source (at the time of illumination) of a different kind of visual display structure The figure which shows the observation state of the dissimilar visual display structure under no light source (during power failure / light extinction) The figure showing an example of the specific structure of a heterogeneous visual display structure The figure which further expresses one example of the specific structure of a different-type visual display structure

Explanation of symbols

1 heterogeneous visual display structure 2 light transmissive planar substrate
2a Synthetic resin board
2b Sheet-like laminate 3 Perforated sheet
3a Perforated sheet made of thermoplastic resin
3b Perforated portion of perforated sheet made of thermoplastic resin
3c mesh sheet
3d Opening part 4 of mesh sheet 4 Perspective control body 5 Visual display layer (A)
6 Visual display layer (B)
6a Luminescent material containing part
6b No phosphorescent material containing part 7 Weather protection

Claims (10)

  A transparent control body in which a porous sheet is laminated on both a light-transmitting planar base material and both the front surface side or the front surface side and the back surface side, and the visual display layer is formed on the surface of the front surface porous sheet. (A) is provided, and a visual display layer (B) different from the visual display (A) is provided on the entire rear surface of the transparency control body, and the visual display layer (B) is a phosphorescent material. A heterogeneous visual display structure comprising a luminescent material-containing portion and a non-luminescent material-containing material-containing portion, and having a mutual color difference ΔE (JIS-Z-8729) of 10 or less.   The heterogeneous visual display structure according to claim 1, wherein the light-transmitting planar base material is a synthetic resin plate having a thickness of 1 to 10 mm.   The heterogeneous visual display structure according to claim 1, wherein the light-transmitting planar base material is a sheet-like laminate including a fiber fabric as a core material and having a thermoplastic resin layer on one side or more.   The heterogeneous visual display structure according to claim 1, wherein the porous sheet is a perforated sheet made of a thermoplastic resin.   The porous sheet is a mesh sheet that includes a coarse fabric composed of warps and wefts as a core material, and the surfaces of the warps and wefts are coated with a thermoplastic resin. 2. The heterogeneous visual display structure according to claim 1.   The heterogeneous visual display structure according to any one of claims 1 to 5, wherein the visual display layer (A) is formed by gravure printing, screen printing, ink jet printing, transfer printing, and a combination thereof.   The phosphorescent material-containing part of the visual display layer (B) is formed by printing, painting, pasting a shaped article, pasting a cutting sheet, and a combination thereof. Heterogeneous visual display structure.   The phosphorescent material-free portion of the visual display layer (B) is formed by printing, painting, pasting a shaped article, pasting a cutting sheet, and a combination thereof. The described heterogeneous visual display structure.   The heterogeneous visual display structure according to any one of claims 1 to 8, wherein a weatherproof protective layer is provided on the entire surface of the porous sheet including the visual display layer (A).   A transparent control body in which a porous sheet is laminated on both a light-transmitting planar base material and both the front surface side or the front surface side and the back surface side, and the visual display layer is formed on the surface of the front surface porous sheet. (A) is provided, and a visual display layer (B) different from the visual display layer (A) is provided on the entire back surface of the transparency control body, and the visual display layer (B) In a display structure composed of a phosphorescent material-containing portion and a phosphorescent material-free portion and having a color difference ΔE (JIS-Z-8729) of 10 or less, phosphorescent light emission by the phosphorescent material-containing portion Through the holes of the perforated sheet, and the visual display layer (B) is luminescently displayed in the form of dots.

Images