JP2019056836A - Retroreflective sheet - Google Patents

Abstract

To provide a retroreflective sheet which is easy in manufacturing, and by which a pattern formed of an ink layer can be clearly and visually confirmed.SOLUTION: In a retroreflective sheet (101) having a retroreflective laminate (10) and a visible ink layer (21), the retroreflective laminate (10) has a reflection material layer (12) and a transparent spherical body laminate (11), the transparent spherical body laminate (11) has a plurality of transparent spherical bodies, at least a part of the transparent spherical bodies is imbedded into the reflection material layer (12), and the visible ink layer (21) covers at least a part of portions of the followings (i) and (ii), and does not cover apexes of a plurality of the transparent spherical bodies. In the retroreflective sheet (101), (i) the portion is that other than the apexes of a plurality of the transparent spherical bodies, and (ii) the portion is that of the reflection material layer (12) in a clearance of a plurality of the transparent spherical bodies.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a retroreflective sheet, particularly a retroreflective sheet used for authenticity determination.

  A technique using a retroreflective sheet such as a retroreflective printed material is known as a sign for determining the authenticity of a product.

  For example, Patent Document 1 relates to a retroreflective printed material for preventing counterfeiting, and the retroreflective printed material includes a printing substrate, a reflective material printed layer including a reflective material, and a spherical transparent material including a spherical transparent material. It has a printing layer in this order, and the average particle diameter of a spherical transparent body is 10 micrometers or more and less than 50 micrometers. Further, in Patent Document 1, in the above retroreflective printed matter, a print layer is provided between the printing substrate and the reflective material printing layer, and the reflective material printing layer and the spherical transparent material printing layer are used for printing. It describes that it is formed only on a part of the substrate.

JP 2017-19144 A

  An object of the present invention is to provide a retroreflective sheet that is easy to manufacture and that allows the image of an ink layer to be clearly seen. Moreover, the objective of the specific aspect of this invention is to provide the retroreflective sheet | seat which can make the pattern visually recognized different on nonretroreflective conditions and retroreflective conditions.

  The present invention is as follows.

<1> A retroreflective sheet having a retroreflective laminate and a first visible ink layer on the retroreflective laminate,
The retroreflective laminate has a reflector layer and a transparent spherical layer,
The transparent spherical body layer has a plurality of transparent spherical bodies, each transparent spherical body is at least partially embedded in the reflector layer,
The first visible ink layer is a retroreflective sheet that covers at least a part of the following parts (i) and (ii) and does not cover the tops of the plurality of transparent spherical bodies:
(I) a portion other than the tops of the plurality of transparent spheres; and (ii) a portion of the reflector layer in the gap between the plurality of transparent spheres.
<2> When the retroreflective sheet is observed from the transparent spherical body layer side,
The ratio of the area of the exposed portion where the plurality of transparent spheres are not covered with the first visible ink layer to the area of the region where the first visible ink layer is present is 20% or more,
The retroreflective sheet according to <1> above.
<3> The retroreflective sheet according to <1> or <2>, further including a second visible ink layer covering the tops of the plurality of transparent spherical bodies on the retroreflective laminate. .
<4> The retroreflective sheet according to <3>, wherein the first visible ink layer and the second visible ink layer are at least partially overlapped on the retroreflective laminate. .
<5> The retroreflection according to any one of <1> to <3>, further including an invisible ink layer covering the tops of the plurality of transparent spherical bodies on the retroreflective laminate. Sex sheet.
<6> The retroreflective sheet according to <5>, wherein the first visible ink layer and the invisible ink layer are at least partially overlapped on the retroreflective laminate.
<7> The retroreflective sheet according to any one of <1> to <6>, which is for authenticity determination.
<8> Preparing the retroreflective laminate, and printing visible ink on the retroreflective laminate to form the first visible ink layer, <1> to <1. The manufacturing method of the retroreflective sheet as described in any one of 7>.
<9> The method according to <8>, wherein the visible ink has a viscosity of 0.3 poise or less.

  The retroreflective sheet of the present invention can be easily manufactured and the pattern can be clearly seen. Moreover, in a specific aspect, the retroreflective sheet | seat of this invention can make the pattern visually recognized different on non-retroreflective conditions and retroreflective conditions.

FIG. 1 is a schematic cross-sectional view showing a laminated structure of retroreflective sheets in the first embodiment of the present invention. FIG. 2 is a schematic cross-sectional view showing a laminated structure of retroreflective sheets in the second embodiment of the present invention. FIG. 3 is a schematic cross-sectional view showing a laminated structure of retroreflective sheets in the third aspect of the present invention. 4 shows (a) a coating state, (b) a pattern visually recognized under non-retroreflective conditions, and (c) a retroreflective sheet for the retroreflective sheet according to the second embodiment of the present invention shown in FIG. It is a schematic top view which shows the pattern visually recognized on conditions. FIG. 5 shows (a) a coated state, (b) a pattern visually recognized under non-retroreflective conditions, and (c) a retroreflective sheet for the retroreflective sheet according to the third aspect of the present invention shown in FIG. It is a schematic top view which shows the pattern visually recognized on conditions. 6 is an enlarged top view photograph of the retroreflective sheet obtained in Example 1. FIG. FIG. 7 is an enlarged top view photograph of the retroreflective sheet obtained in Comparative Example 1. FIG. 8 is an enlarged top view photograph of the retroreflective sheet obtained in Example 2. FIG. 9 is an enlarged top view photograph of the visible ink layer forming region taken under the non-recursive condition and the recursive condition for the retroreflective sheet obtained in Example 2.

<Retroreflective sheet>
The retroreflective sheet of the present invention is a sheet having a retroreflective laminate and a first visible ink layer on the retroreflective laminate. Here, the retroreflective laminate includes a reflector layer and a transparent sphere layer, the transparent sphere layer includes a plurality of transparent spheres, and each transparent sphere is at least partially embedded in the reflector layer. It is. The first visible ink layer covers at least part of the following parts (i) and (ii) and does not cover the tops of the plurality of transparent spheres: (i) the plurality of transparent spheres And (ii) a portion of the reflector layer in the gap between the plurality of transparent spherical bodies. The first visible ink layer covering the part (i) and the first visible ink layer covering the part (ii) may be integrated continuously.

  In this specification, the term “retroreflection condition” refers to a condition in which light is incident on an object from a light source and the retroreflected light reflected in the incident direction is observed, that is, the light source position and the observation position are substantially the same. It means the condition of position. In this specification, the “non-retroreflective condition” refers to a condition in which light is incident on an object from a light source and scattered light scattered in a direction other than the incident direction is observed, that is, the position of the light source and the observation condition. This means that the position is different.

  In the present specification, “visible ink” refers to ink that can be visually recognized under non-retroreflective conditions, and “invisible ink” refers to ink that is visually visible under nonretroreflective conditions. Refers to ink that is impossible or difficult to see.

  In the prior art, when obtaining a retroreflective sheet having a printed pattern, a printed pattern with a visible ink layer is formed on a substrate, and a retroreflective laminate is laminated thereon. According to the method of laminating the retroreflective laminate on the printed pattern after forming the printed pattern in this way, in addition to the problem that the manufacturing process is complicated, the observer can only print the printed pattern through the retroreflective laminate. Cannot be visually recognized, and the printed pattern to be visually recognized may become unclear.

  On the other hand, since the retroreflective sheet of the present invention can form a pattern printing with a visible ink layer on the retroreflective laminate, it is easy to manufacture and the observer does not pass through the retroreflective laminate. The printed pattern can be directly recognized, and the printed pattern can be clearly seen.

(First aspect)
In FIG. 1, the schematic sectional drawing of the laminated structure of the retroreflective sheeting in the 1st aspect of this invention is shown.

  The retroreflective sheet (101) of FIG. 1 has a retroreflective laminate (10) and a first visible ink layer (21) on the retroreflective laminate. The retroreflective laminate (10) has a reflector layer (12) and a transparent spherical body layer (11). The transparent spherical body layer (11) has a plurality of transparent spherical bodies, and at least a part of each transparent spherical body is embedded in the reflector layer.

  The first visible ink layer (21) covers a portion other than the top of the plurality of transparent spheres and the portion of the reflector layer in the gap between the plurality of transparent spheres on the retroreflective laminate. The top of the transparent sphere is not covered.

  In the retroreflective sheet (101) of FIG. 1, the first visible ink layer (21) is present on the retroreflective laminate (10). Therefore, when the retroreflective sheet (101) is visually observed under non-retroreflective conditions, the observer clearly sees the pattern formed by the first visible ink layer (21) on the retroreflective laminate (10). Visible to.

  On the other hand, under retroreflective conditions, incident light (51a) to the region where the first visible ink layer (21) does not exist is converted into retroreflected light (51b) by the transparent spherical body of the transparent spherical body layer (11). Retroreflected in the incident direction.

  In addition, since the first visible ink layer (21) does not cover the top of the transparent spherical body of the transparent spherical body layer (11), the region where the first visible ink layer (21) is present under the retroreflective condition. The incident light (52a) is reflected by the transparent spherical body of the transparent spherical body layer (11) in the same manner as the incident light (51a) to the region where the first visible ink layer (21) is not present ( 52b) is retroreflected in the incident direction. Therefore, the retroreflective sheet can exhibit retroreflective properties even in the region where the first visible ink layer (21) is present under the retroreflective condition. The pattern formed with one visible ink layer (21) becomes invisible or difficult to visually recognize.

(Second aspect)
In the second aspect of the present invention, the retroreflective sheet may further have a second visible ink layer covering the tops of the plurality of transparent spherical bodies on the retroreflective laminate.

  In FIG. 2, the schematic sectional drawing of the laminated structure of the retroreflective sheet | seat in the 2nd aspect of this invention is shown.

  The retroreflective sheet (102) in FIG. 2 has a second visible ink layer (22) covering the top of a plurality of transparent spherical bodies on the retroreflective laminate (10). This is the same as the retroreflective sheet (101) in FIG.

  In the retroreflective sheet (102) of FIG. 2, the first visible ink layer (21) and the second visible ink layer (22) partially overlap and have an overlapping region (40) of both ink layers. doing.

  Here, when both the first visible ink layer (21) and the second visible ink layer (22) are circular and have an overlapping region (40) of both ink layers, these ink layers are placed on the upper surface. When observed from the above, it becomes as shown in FIG.

  When the retroreflective sheet (102) shown in FIG. 4 (a) is observed under non-retroreflective conditions, as shown in FIG. 4 (b), the first visible ink layer (21) and the second visible ink layer The pattern (21, 22) formed in (22) is visually recognized.

  On the other hand, when the retroreflective sheet (102) shown in FIG. 4 (a) is observed under the retroreflective condition, as described above with respect to the retroreflective sheet (101) of FIG. Retroreflection is not hindered by the presence of (21). Therefore, in the region where the second visible ink layer (22) covering the top of the transparent sphere is not present, the incident light (51a) to the region where the first visible ink layer (21) is not present, and Both incident light (52a) to the region where the first visible ink layer (21) is present are retroreflected in the incident direction as retroreflected light (51b, 52b). As a result, even in the region where the first visible ink layer (21) is present, the pattern formed by the first visible ink layer (21) becomes invisible due to glare due to the retroreflected light (52b), or It becomes difficult to see.

  On the other hand, in the region where the second visible ink layer (22) covering the top of the transparent sphere is present, retroreflection is suppressed by the second visible ink layer (22). Regardless of the presence or absence of the visible ink layer (21), incident light (53a, 54a) is scattered as scattered light (53b, 54b), respectively. Therefore, when the retroreflective sheet (102) shown in FIG. 4 (a) is observed under retroreflective conditions, the pattern formed by the second visible ink layer (22) is shown in FIG. 4 (c). It is visually recognized as a dark part.

  The retroreflective sheet according to the second aspect of the present invention can make the visually recognized pattern different under the non-retroreflective condition and the retroreflective condition by such a mechanism.

(Third aspect)
In the third aspect of the present invention, the retroreflective sheet may further have an invisible ink layer covering the tops of the plurality of transparent spherical bodies on the retroreflective laminate.

  In FIG. 3, the schematic sectional drawing of the laminated structure of the retroreflective sheet | seat in the 3rd aspect of this invention is shown.

  The retroreflective sheet (103) in FIG. 3 has a non-visible ink layer (31) covering the top of a plurality of transparent spherical bodies on the retroreflective laminate (10), except that It is the same as that of the retroreflective sheet (101).

  In the retroreflective sheet (103) shown in FIG. 3, the first visible ink layer (21) and the invisible ink layer (31) partially overlap and have an overlapping region (41) of both ink layers. Yes.

  Here, when both the first visible ink layer (21) and the invisible ink layer (31) are circular and have an overlapping region (41) of both ink layers, these ink layers were observed from the upper surface. The area is as shown in FIG.

  When the retroreflective sheet (103) shown in FIG. 5 (a) is observed under non-retroreflective conditions, the invisible ink layer (31) is not visible, and the first visible ink is shown in FIG. 5 (b). The pattern formed by the layer (21) is visually recognized.

  On the other hand, when the retroreflective sheet (103) shown in FIG. 5 (a) is observed under the retroreflective condition, as described above with respect to the retroreflective sheet (101) of FIG. Retroreflection is not hindered by the presence of (21). Therefore, in the region where the invisible ink layer (31) covering the top of the transparent spherical body does not exist, the incident light (51a) to the region where the first visible ink layer (21) does not exist, and the first Both the incident light (52a) to the region where the visible ink layer (21) exists are retroreflected in the incident direction as retroreflected light (51b, 52b). As a result, even in the region where the first visible ink layer (21) is present, the pattern formed by the first visible ink layer (21) becomes invisible due to glare due to the retroreflected light (52b), or It becomes difficult to see.

  On the other hand, in the region where the invisible ink layer (31) covering the top of the transparent spherical body is present, retroreflection is suppressed by the invisible ink layer (31), and the first visible ink layer (21 ), The incident light (55a, 56a) is not retroreflected and scattered as scattered light (55b, 56b). Therefore, when the retroreflective sheet (103) shown in FIG. 5 (a) is observed under the retroreflective condition, the pattern formed by the invisible ink layer (31) is visually recognized as a dark part as shown in FIG. 5 (c). Is done.

  The retroreflective sheeting according to the third aspect of the present invention can make a visually recognized pattern different under non-retroreflective conditions and retroreflective conditions by such a mechanism.

  The third aspect may be applied in a superimposed manner with the second aspect. That is, the retroreflective sheet of the present invention has a first visible ink layer that does not cover the tops of the plurality of transparent spheres on the retroreflective laminate, and covers the tops of the plurality of transparent spheres. The second visible ink layer may be provided, and the invisible ink layer covering the tops of the plurality of transparent spherical bodies may be provided.

  Hereinafter, each of the components of the retroreflective sheet according to the present invention will be described using a non-limiting embodiment as an example.

(Retroreflective laminate)
The retroreflective laminate in the retroreflective sheet of the present invention is a laminate having a reflector layer and a transparent spherical layer. In the retroreflective laminate, the transparent sphere layer has a plurality of transparent spheres, and at least a part of each transparent sphere is embedded in the reflector layer.

  The reflector layer is provided so as to be in direct contact with a plurality of transparent spheres of the transparent sphere layer or indirectly through another layer, and has a function of reflecting light incident on the transparent sphere layer. Have. The reflective material layer may be composed of, for example, a pearl pigment, a vapor-deposited metal thin film, or the like.

  The transparent spherical body layer is a layer having a plurality of transparent spherical bodies. Examples of the transparent spherical body include glass beads and resin beads. For example, the transparent spherical body has an average particle size of 10 μm or more or 50 μm or more, 1 cm or less, 1 mm or less, 100 μm or less, or 50 μm or less, and a refractive index of about 1.9 to 2.2. It's okay.

  At least a part of each transparent spherical body of the transparent spherical body layer is embedded in the reflector layer. From the viewpoint of increasing the reflectance of the retroreflective laminate, each transparent sphere of the transparent sphere layer is, for example, 10% or more or 20% or more and 70% or less of the area of the hemisphere facing the reflector layer side. About 60% or less may be embedded in the reflector layer.

  In the transparent spherical body layer, the plurality of transparent spherical bodies may be filled in a close-packed periodic arrangement. However, the transparent spheres do not necessarily need to be filled in the closest periodic arrangement, and may be filled more sparsely or in a non-periodic arrangement. There may be a portion that forms a gap without contacting each other.

  In the retroreflective sheet of the present invention, the exposure rate of the transparent sphere is, for example, 20% or more, 25% or more, 30% or more, 35% or more, or 40%, from the viewpoint of ensuring good retroreflectivity. It may be above. On the other hand, from the viewpoint of ensuring the visibility of the pattern constituted by the visible ink layer under non-retroreflective conditions, the exposure rate of the transparent spherical body is, for example, 60% or less, 55% or less, 50% or less, It may be 45% or less, or 40% or less.

  The exposure rate of the transparent sphere is such that when the retroreflective sheet of the present invention is observed from the transparent sphere layer side, the transparent sphere becomes the first visible ink in the region where the first visible ink layer exists. Defined as the ratio of the area of the uncovered exposed area to the area of the area where the first visible ink layer is present. Here, the area of the region where the first visible ink layer is present includes the area of the exposed portion in which the plurality of transparent spherical bodies are not covered with the first visible ink.

The exposure rate of the transparent spherical body in the retroreflective sheet of the present invention is such that a photographic image obtained by photographing an area where the first visible ink layer is present, a dark color part (formation part of the first visible ink layer) and a light color part. and the binarization (the exposed portion of the transparent spheres), using the area a _B of the area a _D and bright portions of the dark portion is a value calculated by the following equation.
Exposure rate of transparent spherical body (%) = {A _B / (A _B + A _D )} × 100

  The retroreflective laminate may further include a base material layer, an adhesive layer, and the like on the surface of the reflective layer opposite to the transparent spherical layer. The retroreflective laminate may further have an additional picture layer between the transparent spherical layer and the base material layer. For the pattern layer in this case, for example, the description in Patent Document 1 may be referred to.

  The retroreflective laminate in the present invention may be a commercially available retroreflective film. For example, an open type retroreflective film “LIGHT FORCETM LFU-1400” manufactured by Maruhito Corporation may be used.

(First and second visible ink layers)
The first and second visible ink layers in the retroreflective sheet of the present invention are layers made of visible ink that can be visually recognized under non-retroreflective conditions, and the retroreflective sheet is observed from the transparent spherical body layer side. When you do, you may form any picture. This arbitrary pattern may be, for example, characters, symbols, other designs, and combinations of two or more thereof.

  The first and second visible ink layers in the retroreflective sheet of the present invention are each composed of a known colored pigment, colored dye, or glitter pigment, or a cured product of an ink containing two or more of these. It's okay. In general, the pearl ink classified as “transparent ink” is included in the visible ink in the present invention because the interference color can be visually recognized when the cured product is visually observed under non-recursive conditions.

(Invisible ink layer)
The invisible ink layer in the retroreflective sheet of the present invention is an ink layer in which a lower pattern or the like can be visually recognized through this ink layer, and is a layer made of invisible ink that cannot be visually recognized particularly under non-retroreflective conditions. This invisible ink layer has a function to prevent the invisible ink layer existing area of the retroreflective laminate from retroreflecting by covering the tops of the plurality of transparent spherical bodies of the retroreflective laminate. Have The invisible ink layer forms an arbitrary pattern including, for example, letters, symbols, other designs, and combinations of two or more of these when the retroreflective sheet is observed from the transparent spherical body layer side. It's okay.

  The invisible ink layer in the retroreflective sheet of the present invention may be composed of a cured product of invisible ink such as medium ink.

<Method for producing retroreflective sheet>
The method of the present invention for producing the retroreflective sheet of the present invention comprises:
Preparing a retroreflective laminate, and printing visible ink on the retroreflective laminate to form a first visible ink layer;
including.

  In the method for producing a retroreflective sheet of the present invention, a visible ink is printed on the retroreflective laminate to form a second visible ink layer, or an invisible ink is printed to form an invisible ink layer. Or both of them may be further included.

(Retroreflective laminate)
The retroreflective laminate may have a reflector layer and a transparent spherical layer, and may be a commercial product. About the retroreflective laminated body used for the manufacturing method of the retroreflective sheet | seat of this invention, you may refer the description regarding the retroreflective laminated body in the retroreflective sheet | seat of this invention.

(Formation of the first visible ink layer)
The ink used for forming the first visible ink layer preferably has a low viscosity. By using a low-viscosity ink, when visible ink is printed on the retroreflective laminate, the visible ink in contact with the transparent sphere layer does not stay on top of the plurality of transparent spheres. You may move to at least one of the part other than the top part on a transparent spherical body, and the part of the reflecting material layer of the space | interval of several transparent spherical bodies, and you may make it harden | cure after that. According to this method, the retroreflective sheet of the present invention can be easily produced. In order to enable such visible ink movement, printing of visible ink on the retroreflective laminate maintains the retroreflective laminate in a substantially horizontal state with the reflector layer vertically downward. May be done.

  From the viewpoint of facilitating the movement of the visible ink and forming a desired first visible ink layer, the viscosity of the visible ink used for printing is, for example, 0.3 poise or less, 0.2 poise or less, 0. It may be 1 Poise or less, 0.08 Poise or less, or 0.05 Poise or less. On the other hand, from the viewpoint of making the first visible ink layer formed visible as a desired pattern under non-recurring reflection conditions, the viscosity of the visible ink is, for example, 0.003 Poise or more, 0.005 Poise or more, It may be 0.007 Poise or more, or 0.01 Poise or more.

  The viscosity of these visible inks is determined according to JIS Z 8803: 2011 “Method for measuring viscosity of liquid” (for example, a tuning-fork type vibration viscometer (model number: manufactured by A & D Co., Ltd.)). SV-1A VIBRO VISCOMETER), etc.) and measured at a temperature of 25 ° C. and a relative humidity of 55% RH.

  Specifically, the viscosity of these visible inks is measured by the following method, for example. That is, for example, a vibration viscometer is started up in a room managed at a room temperature of 25 ° C. and a relative humidity of 55% RH, and calibration is performed. Thereafter, the measurement of the viscosity of the visible ink sample with a vibration viscometer is started, and the measured value after the value is stabilized after 15 seconds or more is adopted as the viscosity of the visible ink. The visible ink sample to be measured is set in the measuring device with 50 mL in a 100 mL disposable cup, for example.

  Printing for forming the first visible ink layer may be performed by a known method, and may be performed by an appropriate method such as letterpress printing, flexographic printing, gravure printing, offset printing, screen printing, and inkjet printing. Among these, inkjet printing is preferable because it can be applied to low-viscosity ink and can be printed in a state in which the retroreflective laminate is maintained in a substantially horizontal state.

  In the formation of the first visible ink layer, the exposure rate of the transparent spheres can be adjusted by appropriately adjusting the viscosity, amount, etc. of the visible ink to be used and the surface state of the transparent spheres in the retroreflective laminate. Can be adjusted arbitrarily. As needed, you may adjust the exposure rate of a transparent spherical body by performing visible ink application | coating several times with the printing method of the same kind or a different kind.

(Formation of second visible ink layer)
The optional formation of the second visible ink layer is preferably performed using a desired visible ink on at least the transparent spherical layer of the retroreflective sheet after forming the first visible ink layer. The printing method may be used.

  The second visible ink layer covers the tops of the plurality of transparent spheres. Therefore, the visible ink for forming the second visible ink layer may be cured in a state where at least a part of the visible ink stays on top of the plurality of transparent spherical bodies after contacting the transparent spherical layer during printing. In order to enable formation of such a visible ink layer, the visible ink for forming the second visible ink layer preferably has a relatively high viscosity.

  The viscosity of the visible ink for forming the second visible ink layer may be, for example, 0.5 poise or more, 1.0 poise or more, 5.0 poise or more, 10 poise or more, or 50 poise or more, for example, 10,000 poise. Hereinafter, it may be 5,000 Poise or less or 1,000 Posei or less.

  The viscosities of visible inks having relatively high viscosities are determined according to JIS Z 8803: 2011 "Method for measuring viscosity of liquid", for example, a B-type rotational viscometer (for example, a B-type rotational viscometer manufactured by BROOK FIELD Model No .: DV-II) etc.) and measured at a temperature of 25 ° C. and a relative humidity of 55% RH.

  Specifically, for example, it is measured by the following method. That is, for example, a B-type rotational viscometer is started up in a room managed at a room temperature of 25 ° C. and a relative humidity of 55% RH, and calibration is performed. Thereafter, spindle # 25 is attached to the apparatus, and the rotation speed is set to 50 rpm. Thereafter, the measurement of the viscosity of the visible ink sample with a B-type rotational viscometer is started, and the measured value after the value has stabilized after 30 seconds or more is adopted as the viscosity of the visible ink. The visible ink sample to be measured is set in the measuring device with 50 mL in a 100 mL disposable cup, for example.

(Formation of invisible ink layer)
The invisible ink layer optionally formed is preferably a known printing method using the above-mentioned invisible ink on the transparent spherical layer of the retroreflective sheet after forming at least the first visible ink layer. May be done by:

  The invisible ink layer covers the tops of the plurality of transparent spheres. Therefore, the invisible ink for forming the invisible ink layer may be cured in a state where at least a part of the invisible ink stays on top of the plurality of transparent spherical bodies after contacting the transparent spherical body layer at the time of printing. In order to make it possible to form such an invisible ink layer, the invisible ink for forming the invisible ink layer preferably has a relatively high viscosity.

  The viscosity of the invisible ink for forming the invisible ink layer may be, for example, 0.5 poise or more, 1.0 poise or more, 5.0 poise or more, 10 poise or more, or 50 poise or more, for example, 10,000 poise or less, , 1,000 Poise or less, or 1,000 Posei or less.

  The viscosity of these invisible inks is measured using a B-type rotational viscometer in accordance with JIS Z 8803: 2011 “Method for measuring viscosity of liquid” under conditions of a temperature of 25 ° C. and a relative humidity of 55% RH. Value. Specifically, the measurement may be performed in the same manner as the measurement of the viscosity of the visible ink having a relatively high viscosity for forming the second visible ink layer.

<Example 1>
As a retroreflective laminate, an open-type retroreflective film (manufactured by Maruhito Co., Ltd., product name “LIGHT FORCETM LFU-1400”, average diameter of transparent spherical body 45 μm) is used, and the transparent spherical body layer side surface is used. The visible ink and the invisible ink are respectively printed in this order under the following conditions to coat the visible ink layer that does not cover the tops of the transparent spheres and the tops of the transparent spheres. An invisible ink layer was formed to produce the retroreflective sheet of Example 1.

(Formation of visible ink layer)
Printing method: inkjet printing, drop-on-demand system Printing device: manufactured by Canon Inc., inkjet printer, product name “MG7730”, resolution 9,600 dpi × 2,400 dpi
Visible ink: manufactured by Canon Inc., ink cartridge BCI-371 magenta, viscosity 1-5 mPas (0.01-0.05 Poise)
Pattern: Circle with a diameter of 10mm (solid printing)

(Formation of invisible ink layer)
Printing method: Letterpress printing Invisible ink: Transparent offset ink made by T & K TOKA Co., Ltd. Pattern: Print a circle with a diameter of 10 mm (solid printing) by shifting the circle of the visible ink layer from the center by 5 mm

  When the retroreflective sheet after the formation of the visible ink layer and the invisible ink layer was observed under non-recursive conditions, a magenta circle due to the visible ink layer was visually recognized. When the same retroreflective sheet was visually recognized with a retroreflective loupe, the visible ink layer was not visible and the circle of the invisible ink layer was observed as a dark part.

  About the retroreflective sheet obtained in Example 1, the enlarged upper surface photograph of the edge part of a visible ink layer was shown in FIG. Referring to FIG. 6, the visible ink is present in the portion other than the top on the plurality of transparent spheres and in the portion of the reflector layer in the gap between the plurality of transparent spheres, but covers the top of the plurality of transparent spheres. It can be confirmed that they are not.

<Comparative example 1>
The visible ink layer covering the tops of the plurality of transparent spheres and the tops of the plurality of transparent spheres are coated in the same manner as in Example 1 except that the visible ink is printed under the following conditions. A retroreflective sheet of Comparative Example 1 having an invisible ink layer was produced.

(Formation of visible ink)
Printing method: Letterpress printing Ink: Made by T & K TOKA Co., Ltd., product name “BEST ONE Crimson”

  When the retroreflective sheet of Comparative Example 1 was observed under non-recursive conditions, a visible ink layer circle was visually recognized. However, when these retroreflective sheets are viewed with a retroreflective loupe, the circle of the invisible ink layer is observed as a dark portion and the circle of the visible ink layer is also observed as a dark portion, and the visible ink layer and the invisible ink layer are observed. The pattern of the invisible ink layer in the overlapping part with the layer was not visible.

  About the retroreflective sheet | seat obtained in the comparative example 1, the enlarged upper surface photograph of the edge part of a visible ink layer was shown in FIG. When FIG. 7 is seen, it can confirm that the top part of a some transparent spherical body is coat | covered with the visible ink layer.

<Example 2>
In this example, the relationship between the exposure rate of the transparent spherical body and the visibility and retroreflectivity of the visible ink layer was examined.

  A 10 mm diameter circle (solid print) pattern was formed on the retroreflective laminate by the same method as in Example 1 except that the number of inkjet printing was set to 2, 3, 6, and 8. Each visible ink layer was formed, and the exposure rate of the transparent spherical body, the visibility of the visible ink layer, and the retroreflectivity of the obtained retroreflective sheet were examined.

The exposure rate of the transparent sphere was measured as follows. That is, a partial region (388 μm × 292 μm) of the portion where the visible ink layer was formed on the retroreflective laminate was photographed with a digital microscope manufactured by LEICA, model name “DVM5000”. The obtained photographic image is binarized into a dark color part (visible ink layer forming part) and a light color part (exposed part of transparent spherical body) by image processing software (manufactured by Adobe, product name “Photoshop ver. CC2015”). , using the area a _B of the area a _D and bright portions of the dark portion, the value calculated by the following equation, and the exposure ratio.
Exposure rate of transparent spherical body (%) = {A _B / (A _B + A _D )} × 100

  The visibility of the visible ink layer was examined by visual observation under non-recursive conditions to determine whether or not the printed circle shape could be identified. The retroreflectivity was evaluated by the following criteria by observing the state of retroreflection in a circle printing region with a retroreflection loupe for one sample arbitrarily selected from a plurality of samples obtained in a plurality of tests.

<Evaluation criteria for retroreflectivity>
Good: When the visible ink layer is not visible or hardly visible under retroreflective conditions and retroreflected light is observed Yes: When the visible ink layer is slightly visible and retroreflected light is observed under retroreflective conditions

  The results are shown in Table 1 and FIG. Moreover, about the retroreflective sheet | seat obtained by making the frequency | count of inkjet printing into 3 times and 6 times, the enlarged upper surface photograph of the visible ink layer formation area image | photographed on the nonrecursive condition and the recursive condition, respectively was shown in FIG.

  From the above results, the retroreflective sheet of the present invention in which the tops of the plurality of transparent spheres are not coated in the visible ink layer forming region is excellent in the visibility of the visible ink layer under non-recursive conditions, and the recursive conditions Below, even if it was the formation area of the visible ink layer, it showed favorable retroreflectivity, and it was verified that the visible ink layer is not visually recognized or is difficult to visually recognize.

  The retroreflective sheet of the present invention can be suitably used as, for example, a novel design article or a retroreflective article for authenticity determination.

DESCRIPTION OF SYMBOLS 10 Retroreflective laminated body 11 Transparent spherical body layer 12 Reflective material layer 21 1st visible ink layer 22 2nd visible ink layer 31 Invisible ink layer 40, 41 Overlapping area | region 51a, 52a, 53a, 54a, 55a, 56a Incident Light 51b, 52b, 53b, 54b, 55b, 56b Reflected light or scattered light 101 Retroreflective sheet in the first aspect 102 Retroreflective sheet in the second aspect 103 Retroreflective sheet in the third aspect

Claims (9)

A retroreflective sheet having a retroreflective laminate and a first visible ink layer on the retroreflective laminate,
The retroreflective laminate has a reflector layer and a transparent spherical layer,
The transparent spherical body layer has a plurality of transparent spherical bodies, each transparent spherical body is at least partially embedded in the reflector layer,
The first visible ink layer is a retroreflective sheet that covers at least a part of the following parts (i) and (ii) and does not cover the tops of the plurality of transparent spherical bodies:
(I) a portion other than the top of the plurality of transparent spheres, and (ii) a portion of the reflector layer in the gap between the plurality of transparent spheres. When the retroreflective sheet is observed from the transparent spherical body layer side,
The ratio of the area of the exposed portion where the plurality of transparent spherical bodies are not covered with the first visible ink layer to the area of the region where the first visible ink layer is present is 20% or more.
The retroreflective sheet according to claim 1.   The retroreflective sheet according to claim 1 or 2, further comprising a second visible ink layer covering the top of the plurality of transparent spherical bodies on the retroreflective laminate.   The retroreflective sheet according to claim 3, wherein the first visible ink layer and the second visible ink layer at least partially overlap on the retroreflective laminate.   The retroreflective sheet according to any one of claims 1 to 3, further comprising an invisible ink layer covering tops of the plurality of transparent spherical bodies on the retroreflective laminate.   The retroreflective sheet according to claim 5, wherein the first visible ink layer and the invisible ink layer at least partially overlap on the retroreflective laminate.   The retroreflective sheet according to any one of claims 1 to 6, which is for authenticity determination. Preparing the retroreflective laminate, and printing visible ink on the retroreflective laminate to form the first visible ink layer. A method for producing the retroreflective sheet according to Item.   The method according to claim 8, wherein the viscosity of the visible ink is 0.3 poise or less.