JP5597875B2 - Latent image printed matter - Google Patents

Description

  The present invention is particularly suitable for security printed matter such as banknotes, passports, securities, identification cards, cards, and passports that require an anti-counterfeit effect, and a latent image whose image changes in accordance with a change in observation angle. It relates to printed matter.

  Recent advances in digital equipment such as scanners, printers, and color copiers have made it possible to easily produce elaborate copies of valuable prints. As one of the anti-counterfeiting techniques for preventing duplication and forgery, there have been many ones to which an optical security element represented by a hologram whose image changes depending on the observation angle is attached.

  However, unlike conventional anti-counterfeiting technology, which is formed by printing with ink, holograms are formed using complex manufacturing processes and special materials, making them more difficult to manufacture compared to conventional anti-counterfeit prints. It is time consuming and extremely expensive. From this, special light reflective powders such as metal ink, interference mica, oxidized flake mica, pigment coated aluminum flakes and optically changing flakes are blended into the ink or paint, By using a complicated halftone dot configuration, forgery prevention printed matter that can be formed by a general printing method that realizes an image change similar to a hologram has appeared.

  Although the applicant uses general and relatively inexpensive materials and simple printing means, the information recognized by the human eye at a specific part in the printed material is observed at a specific observation angle. An application for an anti-counterfeit information carrier that changes to completely different information by changing the angle has been filed (see, for example, Patent Document 1).

JP 2008-188973 A

  However, in the printed matter described in Patent Document 1, when a latent image is formed by mixing a luminescent pigment or a luminescent dye with transparent ink, a luminescent image that appears by irradiating the printed matter with UV light is under specular reflection light. There is a problem that it becomes only the same image as the latent image that appears in In order to make the latent image and the luminescent image different from each other, it is necessary to use two types of transparent ink, a transparent ink containing a luminescent pigment and a transparent ink containing no luminescent pigment. When included, it was necessary to use three types of inks in total.

  Further, a patent application filed by the present applicant as an image line structure that has an effect of changing a visual image under diffuse reflected light, a visual image under regular reflected light, and a visual image during UV irradiation to a different image. As in the configuration described in 2011-036928, when the two types of image lines forming the second image have a region (K) that overlaps in the S2 direction illustrated in FIG. In the unlikely event that an image line that should overlap with the background image line forming the first image is formed on the base material due to printing misalignment, the visibility of the image that appears during UV irradiation may be reduced. Furthermore, the visual image under specular reflection and the visual image at the time of UV irradiation interfere with each other, and as shown in FIG. There was a possibility.

  In view of the above circumstances, the present invention has an effect of switching an image between diffuse reflected light and regular reflected light using ink containing a glittering material and transparent ink, and further appears under regular reflected light. An object of the present invention is to provide a latent image printed matter that can enhance the effect of preventing forgery by making the latent image and the light-emitting image appearing during UV irradiation a negative-positive image.

  The latent image printed material according to the present invention includes a printed image on at least a part of the substrate, and the printed image includes a glittering material having a UV absorbing ability and is formed of a material having a color different from that of the substrate. A second image formed of a transparent material including a luminescent material is formed on the first image, the first image has a background portion and an information portion, and the background portion has a background image line. A plurality of background image lines arranged in a predetermined direction at a predetermined pitch, and the information section is formed of information information lines arranged in a plurality of information image lines in a predetermined direction at a predetermined pitch. The image includes a positive image portion and a negative image portion. The positive image portion is formed by a group of positive image lines in which a plurality of positive image lines are arranged in a predetermined direction at a predetermined pitch. A group of negative lines in which a plurality of lines are arranged in a predetermined direction at a predetermined pitch. The positive image line and the negative image line have different phases in a predetermined direction, and the background image line, the information image line, and either the positive image line or the negative image line are adjacent to each other within a predetermined pitch. Alternatively, the first image is formed in the observation angle region where the diffuse reflection light is dominant and the other one of the negative image line and the positive image line is formed on the background image line. In the observation angle region where specular reflection light is dominant, the positive image or negative image of the second image is visually recognized, and in the situation where UV light is irradiated, the negative image or positive image of the second image is It is characterized by being visible by emitting light.

  The latent image printed material according to the present invention is characterized in that the image line width in the predetermined direction of the positive image line and the negative image line is the same and not more than the image line width in the predetermined direction of the background image line.

  The latent image printed material according to the present invention is characterized in that the image area ratio of the first image is formed within a range of 20% to 80%.

  The latent image printed material according to the present invention is formed so that the image area ratio of the background portion in the first image is in the range of 20% to 60%, and the image area ratio of the information portion in the first image is It is characterized in that it is formed within the range of 10% to 40% without exceeding the line area ratio of the background image.

  The latent image printed material according to the present invention is characterized in that the predetermined pitch is formed within a range of 0.1 mm to 5 mm.

  According to the latent image printed matter of the present invention, an image formed with an ink containing a glittering material having UV absorbing ability and an image formed with a transparent ink containing a luminescent pigment are superposed according to a certain rule. Thus, it is possible to obtain a printed matter that can improve the forgery prevention effect in which a latent image that appears under specular reflection light and a light-emitting image that appears during UV light irradiation are different without increasing the number of printing colors.

  In addition, the latent image printed matter of the present invention is an image that appears during UV irradiation when an image line that should overlap the background image line that forms the first image is formed on the substrate by causing a printing shift. However, since the two types of image lines forming the second image do not have the overlapping region (K) shown in FIG. 21A, the visibility under specular reflection light is reduced. The visual images at the time of UV irradiation do not interfere with each other, and the appearing image does not become unclear.

It is explanatory drawing which shows the latent image printed matter by embodiment of this invention. (A) is explanatory drawing of the 1st image contained in latent image printed matter, (b) is explanatory drawing of the 2nd image contained in the latent image printed matter. (A) is explanatory drawing of the background part contained in latent image printed matter, (b) is explanatory drawing of the information part contained in latent image printed matter. (A) is explanatory drawing of the positive image part contained in latent image printed matter, (b) is explanatory drawing of the negative image part contained in latent image printed matter. It is explanatory drawing which shows the positional relationship of the superimposition of the background image line contained in the 1st image in a latent image printed matter, an information image line, the negative image line contained in a 2nd image, and a positive image line. (A) shows an image that appears in the printed image of the latent image print when the observer's viewpoint is in the observation angle region where diffuse reflected light is dominant, and (b) shows that the observer's viewpoint is correct. An image that appears in the printed image of the latent image print when the reflected light is in the dominant observation angle region is shown, and (c) shows an image that appears in the printed image of the latent image print when irradiated with UV light. It is explanatory drawing. (A) shows the 1st image in the printed matter produced with the prior art, (b) is explanatory drawing which shows the 2nd image in the conventional printed matter. It is explanatory drawing of the effect at the time of forming printed matter by a conventional technique, Comprising: (a) is a printed image of the conventional printed matter when an observer's viewpoint exists in the observation angle area | region where diffuse reflected light is dominant. (B) shows an image that appears in a printed image of a conventional printed material when the observer's viewpoint is in an observation angle region where specular reflection light is dominant, and (c) shows the UV It is explanatory drawing which shows the image which appears in the printed image of the conventional printed matter when light is irradiated. It is explanatory drawing which shows the latent image printed matter in one Example. (A) is explanatory drawing of the 1st image contained in the latent image printed matter in one Example, (b) is explanatory drawing of the 2nd image contained in the latent image printed matter in one Example. (A) is explanatory drawing of the 1st background part contained in the latent image printed matter in one Example, (b) is explanatory drawing of the 1st information part contained in the latent image printed matter in one Example. (A) is an explanatory view of a positive image portion included in the latent image printed matter in one embodiment, and (b) is an explanatory view of a negative image portion included in the latent image printed matter in one embodiment. Explanatory drawing which shows the positional relationship of the superimposition of the background image line contained in the 1st image in the latent image printed matter of one Example, the positive image line contained in the information image line and the 2nd image, and the negative image line. It is. (A) shows the image which appears in the printed image of the latent image printed material in one Example, when an observer's viewpoint exists in the observation angle area | region where diffuse reflection light is dominant, (b) shows an observer's viewpoint. The viewpoint shows an image that appears in the printed image of the latent image printed material in one embodiment when the specular reflection light is in the dominant observation angle region, and (c) shows the image in the embodiment when irradiated with UV light. It is explanatory drawing which shows the image which appears in the printed image of latent image printed matter. It is explanatory drawing which shows the latent image printed matter in one Example. (A) is explanatory drawing of the 1st image contained in the latent image printed matter in one Example, (b) is explanatory drawing of the 2nd image contained in the latent image printed matter in one Example. (A) is an explanatory view of a background portion included in a latent image printed material in one embodiment, and (b) is an explanatory diagram of an information portion included in the latent image printed material in one embodiment. (A) is an explanatory view of a positive image portion included in the latent image printed matter in one embodiment, and (b) is an explanatory view of a negative image portion included in the latent image printed matter in one embodiment. Description showing the positional relationship of the overlay of the background image line included in the first image, the information image line, the positive image line included in the second image, and the negative image line in the printed latent image of the embodiment. FIG. (A) shows the image which appears in the printed image of the latent image printed material in one Example, when an observer's viewpoint exists in the observation angle area | region where diffuse reflection light is dominant, (b) shows an observer's viewpoint. The viewpoint shows an image that appears in the printed image of the latent image printed material in one embodiment when the specular reflection light is in the dominant observation angle region, and (c) shows the image in the embodiment when irradiated with UV light. It is explanatory drawing which shows the image which appears in the printed image of latent image printed matter. It is explanatory drawing which shows the conventional problem.

  DESCRIPTION OF EMBODIMENTS Embodiments for carrying out the present invention will be described with reference to the drawings. However, the present invention is not limited to the embodiments described below, and includes various other embodiments within the scope of the technical idea described in the scope of claims.

  In general, when a transparent ink is used, a luminescent pigment, a luminescent dye, or the like is mixed in order to visualize the manufacturing process so that the presence of the transparent ink can be confirmed for quality control. However, the latent image printed material according to the following embodiment is not mixed with a light-emitting pigment or a light-emitting dye in a transparent ink only for the purpose of quality control described above. The latent image to be visualized and the luminescent image to be visualized by being irradiated with UV light have different characteristics.

  A latent image printed matter according to an embodiment of the present invention will be described with reference to the drawings. In the latent image printed material according to the embodiment, an image is formed by an image line.

  Here, the image line is an image element formed by continuously arranging printing halftone dots, which are the minimum units constituting an image in a printed matter, without any gaps in a predetermined direction, for example, straight lines, curved lines, wavy lines, A broken line such as a dotted line or a broken line is included, and any shape of the image line is included in the image line in the present invention.

  FIG. 1 shows a latent image printed material (1) according to this embodiment. The latent image print (1) has a print image (3) on at least a part of the substrate (2). The print image (3) includes a second image on the first image as described later. The images are overlapped.

  The substrate (2) may be any material as long as it has a flat surface, such as fine paper, coated paper, and plastic plate, and is not limited with respect to material, outer shape, dimensions, and the like. . Further, the image formed on the printed image (3) is not limited in color as long as it includes a colored image.

  The print image (3) shown in FIG. 2 has a configuration including the second image (5) shown in FIG. 2 (b) on the upper surface of the first image (4) shown in FIG. 2 (a). . Here, the first image (4) is an image that is visible in an observation angle region in which diffusely reflected light is dominant, and is formed of an ink containing a glittering material having a characteristic of absorbing UV (ultraviolet) light. Has been. The second image (5) is an image that is visible in an observation angle region where specular reflection light is dominant and in a situation where UV light is irradiated, and is a transparent image containing a luminescent material such as a luminescent pigment or a luminescent dye. It is made of ink. Detailed description of these inks will be described later.

  The “observation angle region in which diffusely reflected light is dominant” in the present invention refers to the angle of light incident on the latent image printed matter from the light source other than the region under specularly reflected light and the angle of light reflected from the latent image printed matter. It is an area where there is very little specularly reflected light. Hereinafter, the observation in this region will be described as “under diffuse reflection”.

  In addition, the “observation angle region in which specular reflection light is dominant” in the present invention means that the angle of light incident on the latent image print from the light source is substantially equal to the angle of light reflected from the latent image print, for example, the light source When light is incident on the latent image printed matter at an incident angle of −45 °, this is a region where strong reflected light is generated in the region near the light receiving angle of 45 °. Hereinafter, the observation in this region will be described as “under regular reflection light”.

  In addition, the “situation where UV light is irradiated” in the present invention means that when the latent image printed material is irradiated with UV light, the light emitting material absorbs ultraviolet light and enters an excited state, and then the original base. It is a situation (area) where light emitted in the process of returning to the state can be received. Hereinafter, the observation in this situation will be described as “at the time of UV irradiation”.

  The first image (4) shown in FIG. 2 (a) includes the background part (6) shown in FIG. 3 (a) and the information part (7) shown in FIG. 3 (b).

  As shown in FIG. 3A, the background portion (6) has a background image line in which the background image line (8) having the image line width (W1) is regularly arranged in a predetermined direction at a predetermined pitch (P1). Formed by groups. Here, the predetermined direction means a direction orthogonal to the image line, that is, a vertical direction in the drawing.

  Further, as shown in FIG. 3B, the information section (7) is configured such that the information image line (9) having the image line width (W2) is regularly arranged in a predetermined direction at a predetermined pitch (P1). It is formed by a group of strokes. The information part (7) is first significant information that appears in a normal observation (observation under diffuse reflection) environment.

  As shown in FIGS. 3A and 3B, the background portion (6) and the information portion (7) are formed of the same glitter ink. Here, since the area of the information part (7) overlaps the area of the background part (6) having a certain gradation, a difference in the line area ratio occurs in the background part (6), and the information part The letter “A” (7) is visually recognized by the shading.

  As shown in FIG. 3, the background image line (8) and the information image line (9) do not necessarily have to be formed adjacent to each other as long as they do not overlap each other, but may be formed close to each other. However, in the first image (4), it is necessary to form a non-image area (10) in which neither the background image line (8) nor the information image line (9) exists. In order to sufficiently secure the width (W3) of the region (10), it is desirable that the background image line (8) and the information image line (9) are arranged close to each other within the range of the pitch (P1).

  In the case where the background image line (8) and the information image line (9) are formed so as to overlap with each other, unnecessary shading occurs in the overlapped area, and the shading appears under specular reflection light. It is reflected in the second significant information which is an image of the above, which is not desirable.

  Here, the line area ratio of the first image (4) and the line area ratio of the background part (6) and the information part (7) forming the first image (4) will be described.

  It is desirable to form the image area ratio (ratio of the image area in a certain area) in the first image (4) in the range of 20 to 80%. The reason why the image area ratio of 20% or less is not included is that the background (6) is always required for the first image (4), and the background area is formed with an image area ratio of 20% or more. This is desirable. The reason why the solid and extreme shadows from 80% to 100% are not included is that the first image (4) has an image line of the first image (4) called a non-image area (10). This is because the non-existing region is essential, and it is desirable that the non-image region (10) is similarly formed with a line area ratio of 20% or more.

  In the background portion (6), it is desirable that the gradation is constant, that is, the image area ratio is constant, and the image area ratio is in the range of 20 to 60%. On the background image line (8) of the background portion (6), either a negative image line (13) or a positive image line (14), which will be described later, is formed so as to overlap the background image line (8). Only the image line formed to overlap the image becomes an image that appears under specular reflection light. Therefore, when the width of the background image line (8) is not sufficient, that is, when the image area ratio of the background portion (6) is small, the visibility of an image appearing under regular reflection light is lowered. For this reason, it is not desirable to form the background portion (6) with an image area ratio of 20% or less. In addition to the background part (6), the information part (7) and the non-image area (10) are indispensable for the first image (4), and the ratio between these image lines and areas is considered. Then, it is preferable that the background area (6) keeps the image area ratio to 60% or less.

  The information part (7) is not limited to a binary image and may have multiple gradations, and the image area ratio is preferably in the range of 10 to 40%. This is because when an image is formed with an area ratio of 10% or less, a sufficient density cannot be obtained, and only an image with low visibility can be formed. Further, in order to form with a line area ratio exceeding 40%, it is necessary to greatly reduce the line area area of the background portion (6) and the non-image area (10). This is because the visibility of an image appearing at the point of time and the visibility of an image appearing during UV irradiation are greatly impaired.

  The second image (5) shown in FIG. 2 (b) includes the positive image portion (11) shown in FIG. 4 (a) and the negative image portion (12) shown in FIG. 4 (b). Yes.

  The positive image portion (11) and the negative image portion (12) have second significant information that appears under specular reflection light and UV irradiation, and the positive image portion (11) is positive for the second significant information, The negative image portion (12) is an image expressing the second significant information as a negative, and the image area ratios of the positive image portion (11) and the negative image portion (12) are shown in FIG. Further, it is necessary to be within a range not exceeding the image area ratio of the background portion (6).

  In FIG. 4, the second significant information is the letter “B” of the alphabet, the positive image portion (11) is an image in which the inside of “B” is darkened, and the negative image portion (12) In the image (5), an image other than “B” is darkened, and the inside of “B” is a white image.

  Either the positive image portion (11) or the negative image portion (12) shown in FIGS. 4 (a) and 4 (b) is superimposed on the background portion (6) shown in FIG. 3 (a). Is an image that appears under specular reflection light. On the other hand, at the time of UV irradiation, when the positive image portion (11) appears under the specularly reflected light, that is, the negative image portion (12) appears under the specularly reflected light. When the negative image portion (12) appears, the positive image portion (11) appears as a light emission image.

  As shown in FIG. 4A, the positive image portion (11) is a positive image in which positive image lines (13) having an image line width (W4) are regularly arranged in a predetermined direction at a predetermined pitch (P1). It is formed by a group of lines. Here, the predetermined direction means a direction orthogonal to the image line, that is, a vertical direction in the drawing.

  Further, as shown in FIG. 4B, in the negative image portion (12), the negative image line (14) having the image line width (W5) is regularly arranged in a predetermined direction at a predetermined pitch (P1). It is formed by a negative image group. Here, the predetermined direction means a direction orthogonal to the image line, that is, a vertical direction in the drawing.

  The positive image line (13) and the negative image line (14) are formed with a phase shift in a predetermined direction so as not to overlap each other. 4 (a) and 4 (b), the positive image line (13) and the negative image line (14) are arranged without a gap in a predetermined direction, but there is no problem even if a gap is provided. However, it is not preferable that the positive image line (13) and the negative image line (14) have an overlapping portion in the S1 direction, and there is an overlapping portion in a direction orthogonal to the S1 direction (left and right direction in the figure). must not.

  This is because the second image (5) is a plurality of image lines arranged in a predetermined direction at a pitch (P1), and the phase of a part of one image line is different, so that the positive image portion and the negative image portion are different. This is because it is divided into line portions, a positive image portion (11) is formed by a plurality of positive image portions, and a negative image portion (12) is formed by a plurality of negative image portions. In other words, the image line forming the second image (5) is divided into a positive image line part and a negative image line part because a part of the phase of one image line is different. There will be no overlapping portion in the direction orthogonal to the S1 direction (left and right direction in the figure).

  In the partially enlarged view in FIG. 3, the background image line (8) is indicated by a horizontal stripe image line, the information image line (9) is indicated by a vertical stripe image line, and a partially enlarged image in FIG. In the figure, the positive image line (13) and the negative image line (14) are indicated by hatched image lines. In addition, a similar image is shown in a partially enlarged view in FIG. However, these displays are performed to make it easy to distinguish the configuration of each image line, and each actual image line is not formed by vertical stripes, diagonal stripes, or the like.

  Next, an ink containing a glittering material that absorbs UV (ultraviolet) light that forms the first image, and a transparent ink that contains a luminescent material such as a luminescent pigment or luminescent dye that forms the second image Will be described.

  The light reflecting property of the glittering material is that when the ink containing the glittering material is printed on a general coated paper at a line area ratio of 100%, the lightness value under specular reflection light is 100 or more, and diffuse reflection The difference between the lightness under light (minimum lightness) and the lightness under regular reflection light (maximum lightness) is desirably 50 or more. When ink having only a reflection characteristic lower than this is used, the disappearance effect of the first image under specular reflection light is reduced, and the image change effect that is an effect in the present invention may be lost. is there.

  The first image may be provided with a color such as red, blue, or black. The color of the color pigment may be any hue such as black, red, blue or yellow. For example, the ink that forms the background image line and the information line may be mixed with a coloring pigment together with the glittering material, or the inks may be mixed together. The same image as one image may be formed, and then the same first image may be formed by superimposing with the ink containing the glittering material.

  However, when an excessive amount of pigment is mixed, the gradation difference (difference in density) in the first image becomes too large, or the mixing ratio of the glittering material in the ink decreases, A phenomenon that the first image does not disappear sufficiently in observation under specular reflection light may occur.

  Therefore, when mixing pigments or mixing inks, even when mixing colored pigments of any color, the amount does not exceed a half of the blending ratio of the glittering material in the ink. It is desirable to keep it. In the case where a color is imparted by forming the same image as the first image with colored ink in advance on the ground, a sufficient switching effect can be obtained regardless of the color and the density of the ink used.

  In addition, you may use common metal powder pigments, such as aluminum powder, copper powder, zinc powder, tin powder, brass powder, iron phosphide, titanium oxide, or scaly mica powder, as a glitter material. These pigments not only have the property of strongly reflecting light, but also have the ability to absorb irradiated ultraviolet rays, so that they are the most bright materials for forming the latent image printed matter of the present invention. preferable.

  When using general pearl pigments such as iris pearl pigments and scaly pigments, and functional pigments such as glass flake pigments or cholesteric liquid crystal pigments, light and dark flip-flops that change only the brightness of the first image ( Color flip-flop property (characteristic that changes not only lightness but also hue) that changes not only the lightness but also the hue of the first image can be imparted.

  A functional material such as an IR absorbing pigment, a photochromic pigment, a temperature indicating material, or a thermochromic material may be added to the glittering material. However, when a functional material such as an IR absorbing pigment, a photochromic pigment, a temperature indicating material, or a thermochromic material is added, it needs to be added within a range that does not affect the effect of the latent image printed material in the present invention.

  The ink having the light emitting property such as the light emitting pigment and the light emitting dye for forming the second image needs to be transparent, and the light emission color may be any. It is desirable that the ink has a lower gloss and a matte tone than the ink forming the first image. When a mat-type ink is used, the ratio of blocking the amount of light reaching the first image increases, and the visibility of the second image increases.

  The light reflection characteristics of the mat-based ink are such that when the ink is printed on a general coated paper at a line area ratio of 100%, the lightness value under specular reflection light is 20 or more lower than the lightness value of the glitter ink, and diffusion It is desirable that the difference between the brightness under reflected light (minimum brightness) and the brightness under regular reflected light (maximum brightness) is 30 or less. The image that appears under specular reflection light is visualized by the difference in reflectance between the glitter ink and the matte ink. Therefore, when the difference in brightness between the glitter ink and the mat ink is less than 20, it is difficult to easily visually recognize the image.

  In addition to light-emitting pigments such as fluorescent pigments, phosphorescent pigments, and phosphorescent pigments, functional materials such as IR absorbing pigments, photochromic pigments, temperature indicating materials, and thermochromic materials may be added to the transparent ink. However, when adding functional materials such as IR absorbing pigments, photochromic pigments, temperature indicating materials, and thermochromic materials, it is necessary to select pigments that do not lose transparency, and the effect of the latent image printed matter in the present invention is not affected. Need to add in range.

  FIG. 5 shows an appropriate positional relationship in the superposition of the first image and the second image. The background image line (8) constituting the background part included in the first image and the information image line (9) constituting the information part are arranged in the predetermined direction at the same pitch.

  The positive image line (13) constituting the positive image portion included in the second image is formed so as to overlap the background image line (8). The negative image line (14) constituting the negative image portion included in the second image is formed in the non-image area (10) where neither the background image line (8) nor the information image line (9) is formed. Is done. Here, any image line should not be formed on top of the information image line (9).

  In the present embodiment, an example in which the positive image line (13) is formed on the background image line (8) and the negative image line (14) is formed in the non-image area (10) will be described. As a configuration in which the positions of the positive image line (13) and the negative image line (14) of the second image are reversed, a negative image line (14) is formed on the background image line (8), and a non-image area ( A positive image line (13) may be formed in 10).

  In this case, the second significant information that appears under specular reflection light is in a negative state, and the second significant information that appears during UV irradiation is in a positive state. What is important in the present invention is that either the positive image line (13) or the negative image line (14) is superimposed on the background image line (8), and the positive image line (13) or the negative image line (14). ) Is formed in the non-image region (10), which is not superimposed on the background image (8). As a printing order, the first image is printed, and then the second image is printed.

  Since the positive image line (13) is invisible under diffuse reflection, the positive image portion (11) shown in FIG. 4 (a) does not appear. Under regular reflection light, the positive image line (13) has a strong contrast with the background image line (8) and the information image line (9), and the positive image portion (11) shown in FIG. Appears and becomes visible. However, at the time of UV irradiation, since the UV light is absorbed by the background image line (8) formed with the glitter ink, the positive image line (13) is prevented from emitting light and the positive image shown in FIG. Part (11) does not appear.

  In the non-image area (10), the negative image line (14) formed of transparent ink does not appear under diffuse reflection light or regular reflection light, and is shown in FIG. 4 (b). The negative image portion (12) is invisible. At the time of UV irradiation, the negative image line (14) emits light strongly, and the negative image portion (12) shown in FIG. 4B appears and becomes visible.

  Under regular reflection light, the background portion and the information portion of the first image strongly reflect light, so that the brightness rises at once and changes lightly. Due to this phenomenon, the first significant information that has been visually recognized under diffuse reflected light becomes invisible.

  Here, when the positive image line (13) or the negative image line (14) formed with the transparent ink is formed on the information image line (9) forming the information portion in the first image, the transparent ink is formed. The overlapped area does not disappear because the information part cannot receive and reflect light under regular reflection light, and the positive image part (11) or the negative image part (shown in FIGS. 4A and 4B). 12) will be hindered.

  Therefore, on the information image line (9), neither the positive image line (13) nor the negative image line (14) made of transparent ink is formed so as to overlap with that shown in FIG. The information part (7) can be completely lost.

  As shown in FIGS. 3, 4 and 5, the negative image line (14) constituting the negative image portion of the second image is formed so as not to overlap the background image line (8) and the information image line (9). In order to achieve this, the image line width (W5) of the negative image line (14) is designed to satisfy the image line width (W5) ≦ width (W3) so as to be within the width (W3) of the non-image area (10). In order to form the positive image line (13) on the background image line (8), the image line width (W4) of the positive image line (13) is set to the image line width of the background image line (8). It is necessary to design the image line width (W4) ≦ the image line width (W1) so as to be within the width of (W1).

  As shown in FIGS. 3, 4, and 5, the larger the image area ratio of the negative image portion (12), the higher the visibility of the negative image portion (12) that appears during UV irradiation. It is desirable that the line width (W5) of (14) is designed to be approximately the same as the line width (W3) of the non-image area (10). Similarly, the larger the image area ratio of the positive image portion (11), the higher the visibility of the positive image portion (11) that appears under specular reflection light. It is desirable to design W4) with an image line width substantially the same as the image line width (W1) of the background image line (8).

  However, as the value of the image line width (W5) approaches the width (W3) and the value of the image line width (W4) approaches the image line width (W1), the tolerance for the misalignment at the time of manufacture becomes smaller. Therefore, it is desirable to design the image line width (W1), the image line width (W2), the width (W3), and the image line width (W4) in consideration of the printing accuracy in the printing machine.

  In addition, the predetermined pitch (P1) in the background image line (8), the information image line (9), the positive image line (13), and the negative image line (14) is determined in consideration of print reproducibility, image resolution, and the like. It is desirable to be within a range of 0.1 mm to 5 mm.

  When the above-described configuration is adopted, the positive image line (13) or the negative image line (14) constituting the second image (5) on the information image line (9) constituting the information portion (6). As described above, it is necessary to improve the visibility of the positive image portion (11) appearing under regular reflection light.

  However, even if the positive image line (13) or the negative image line (14) slightly overlaps the information image line (9) due to misalignment during printing, the positive image line (13) The area overlapping the background image line (8) constituting (6) is large, and therefore the influence on the visibility of the positive image portion (11) appearing under specular reflection light is small. Therefore, a case where the positive image line (13) or the negative image line (14) slightly overlaps the information image line (9) is also included in the technical scope of the present invention.

  FIGS. 6A to 6C show the positional relationship between the light source (15) or the UV light source (17), the latent image printed matter (1), and the observer (16) and the visible state of the latent image printed matter (1) in each. Show. As shown in FIG. 6A, under diffuse reflection, that is, as described above, the angle of light incident on the latent image print (1) and the angle connecting the observer (16a) and the latent image print (1). When the image is observed in a significantly different state, the first image is visually recognized by the observer (16a).

  As shown in FIG. 6B, the latent image printed material (1) is subjected to specular reflection light, that is, the angle of light incident on the latent image printed material (1) as described above, the observer (16b) and the latent image. When observing the printed material (1) at an angle that is substantially the same, the positive image portion is visually recognized by the observer (16b).

  As shown in FIG. 6C, when the latent image printed material (1) is observed during UV irradiation by the UV light source (17), the negative image portion is visually recognized by the observer (16c). In this case, an area shaded in gray in FIG. 6C appears.

  Thus, three kinds of images are visually recognized by an excellent switch effect according to the observation state.

  According to the present embodiment, an image appearing under specular reflection light and UV irradiation in a printed matter having an effect that the first significant information and the second significant information are switched under diffuse reflection light and regular reflection light. It is possible to make the image that appears sometimes different from the image in a negative / positive state, and to obtain a higher forgery prevention effect.

  As a comparative example, FIG. 7 briefly introduces the configuration and effects when a similar latent image print is formed on the same quality paper as in the present invention. FIG. 7 shows an example in which a print image (3 ′) composed of a first image (4 ′) and a second image (5 ′) is formed using the same ink using the technique of Patent Document 1. The first image (4 ′) included in the conventional print image (3 ′) has the same configuration as that of the present invention, and the second image (5 ′) is a solid image with a line area ratio of 100%. . The effect in this case is shown in FIG.

  The image observed in the observation under the diffuse reflected light in FIG. 8A is the same as the image of the present invention, and the visibility is exactly the same when formed with the same image area ratio. In the image observed in the observation under specular reflection light in FIG. 8B, the shade of the first significant information “A” is slightly reflected in the second significant information “B”. It will be. This is because the second image (5 ′) shown in FIG. 7 is a solid image, and therefore the second image (5 ′) also appears on the information line in the first image (4 ′). The first significant information and the second significant information generated due to the formation are mixed and the second significant information can be observed, but it is unclear compared with the present invention. The image that appears during UV irradiation in FIG. 8C has the same negative / positive relationship as the image that appears under specular reflection light, and this is the biggest difference from the present invention.

  As described above, the invention of the present application is clearer of the second significant information appearing under specular reflection light and the negative / positive of the second significant information generated during UV irradiation, as compared with the conventional technique using the same configuration and principle. It is characterized by the effect of inversion. In particular, the effect of reversing the negative and positive images of the image appearing under specular reflection light when viewed at first glance is that the same second significant information is visible at first glance, so the difference is not noticeable unless it is known in advance. While it is a small change, it is a change that you will definitely notice if you are informed beforehand. Although it is not easily noticeable if it is not known, providing an effect that can be reliably discriminated by a known person is very effective for the purpose of eliminating counterfeit goods that are exercised by other persons and for arresting counterfeit crimes.

  The printing method of the latent image printed matter in the embodiment can be formed by any printing method such as offset printing, flexographic printing, letterpress printing, gravure printing, screen printing, and intaglio printing. If metal ink can be used, it can also be formed by various digital output machines such as IJP, laser printer, sublimation printer, etc. In this case, the information of the output is changed for each sheet, so-called Variable printing can be performed.

  The embodiments are merely examples, and various modifications can be made within the technical scope of the present invention.

  A first embodiment will be described with reference to FIGS. 9 to 14. FIG. 9 is a diagram showing the latent image printed matter (1-1) of the present invention, and the latent image printed matter (1-1) includes a printed image (3-1) on a substrate (2-1). It consists of

  In the print image (3-1), the second image (5-1) shown in FIG. 10 (b) is superimposed on the first image (4-1) shown in FIG. 10 (a). Made up. In addition, the general white fine paper (Shiraoi made from Nippon Paper Industries) was used for the base material (2-1) shown in FIG.

  First, the first image (4-1) will be described. The first image (4-1) includes the background part (6-1) shown in FIG. 11A and the information part (7-1) shown in FIG. 11B.

  In the background part (6-1), the background image line (8-1) having an image line width of 0.16 mm is continuously arranged at a pitch of 0.50 mm in the S1 direction (direction orthogonal to the image line) in the drawing. The image area ratio is 32%, and the gradation of the entire image is constant.

  In the information section (7-1), an information image line (9-1) having an image line width of 0.16 mm is continuously provided at a pitch of 0.50 mm in the S1 direction (direction orthogonal to the image line) in the figure. It is formed by a group of arranged information lines, and the line area ratio is the same 32%, and is formed by forming the first significant information “A”.

  The background image line (8-1) and the information image line (9-1) are adjacent to each other without a gap, but are not overlapped with each other, and the first image (4-1) Has a non-image area (10-1) having a width of 0.18 mm in which neither the background image line (8-1) nor the information image line (9-1) exists.

  Next, the second image (5-1) will be described. The second image (5-1) includes a positive image portion (11-1) shown in FIG. 12 (a) and a negative image portion (12-1) shown in FIG. 12 (b). The positive image portion (11-1) and the negative image portion (12-1) include the letter “B” of alphabet which is the second significant information that appears under specular reflection light and UV irradiation, and the positive image portion (11 -1) is an image expressing the second significant information as positive, and the negative image portion (12-1) is an image expressing the second significant information as negative.

  In the positive image portion (11-1), the positive image line (13-1) having an image line width of 0.16 mm is continuously arranged at a pitch of 0.5 mm in the S1 direction (direction orthogonal to the image line) in the drawing. In the negative image portion (12-1), the negative image line (14-1) having an image line width of 0.16 mm is formed in the S1 direction (perpendicular to the image line). In this direction, the negative image group is continuously formed at a pitch of 0.5 mm. The positive image line (13-1) and the negative image line (14-1) were formed by shifting the phase by 0.16 mm in the S1 direction so as not to overlap with each other in the horizontal direction and the vertical direction.

  In FIG. 13, the background image line (8-1) and the information image line (9-1) forming the first image, the positive image line (13-1) forming the second image, and The superposition positional relationship with the negative image line (14-1) is shown. First, a first image is formed by a wet offset printing method using silver ink (T & K Silver TKSO) containing an aluminum pigment, which is a glittering material having a property of absorbing UV (ultraviolet) light. A latent image print was formed by overlaying the second image on the first image using the same wet offset printing method using an ink in which 2% of a green luminescent pigment was blended with OP varnish (matt medium made by T & K TOKA). .

  Specifically, in the non-image area (10-1) of the first image (4-1) shown in FIGS. 11 and 12, the negative image portion (12-1) of the second image (5-1). On the background image line (8-1) forming the background portion (6-1) of the first image (4-1). The positive image line (13-1) forming the positive image portion (11-1) of (5-1) was formed by printing together in a positional relationship where they overlap.

  FIG. 14 shows the effect of the latent image print (1-1). As shown in FIG. 14A, when the latent image printed matter (1-1) was observed under diffuse reflection light, the first image was visually recognized by the observer (16a-1). As shown in FIG. 14B, when the latent image printed matter (1-1) was observed under regular reflection light, the positive image portion was visually recognized by the observer (16b-1). As shown in FIG. 14 (c), when the latent image print (1-1) is observed at the time of UV irradiation by the UV light source (17-1), the negative image portion is a luminescent pigment for the observer (16c-1). It was visually recognized in green, which is the emission color. Thus, three kinds of images were visually recognized by an excellent switch effect depending on the observation state.

  A second embodiment will be described with reference to FIGS. 15 to 20. FIG. 15 is a diagram illustrating the latent image printed material (1-2) according to the present invention, and the latent image printed material (1-2) includes a printed image (3-2) on a base material (2-2). It consists of

  In the printed image (3-2), the second image (5-2) shown in FIG. 16 (b) is superimposed on the first image (4-2) shown in FIG. 16 (a). Made up. In addition, common white fine paper (Nippon Paper Industries Shiraoi) was used for the base material (2-2) shown in FIG.

  First, the first image (4-2) will be described. The first image (4-2) includes a background part (6-2) shown in FIG. 17A and an information part (7-2) shown in FIG. 17B.

  In the background part (6-2), a background image line (8-2) having an image line width of 0.16 mm is continuously arranged at a pitch of 0.50 mm in the S1 direction (direction orthogonal to the image line) in the drawing. The image area ratio is 32%, and the gradation of the entire image is constant.

  In the information section (7-2), an information image line (9-2) having an image line width of 0.16 mm is continuously provided at a pitch of 0.50 mm in the S1 direction (direction orthogonal to the image line) in the figure. It is formed by a group of arranged information lines. The information image line (9-2) in Example 2 is composed of gradation images having shading in the image line, the image area ratio is 0% to 32%, and the floor representing the butterfly image. The first significant information having a key is formed.

  The background image line (8-2) and the information image line (9-2) are configured such that the image lines are adjacent to each other without a gap, but are not overlapped, and the first image (4-2) Has a non-image area (10-2) having a width of 0.18 mm in which neither the background image line (8-2) nor the information image line (9-2) exists.

  Next, the second image (5-2) will be described. The second image (5-2) includes a positive image portion (11-2) shown in FIG. 18 (a) and a negative image portion (12-2) shown in FIG. 18 (b). The positive image portion (11-2) and the negative image portion (12-2) include the letter “B” of alphabet which is the second significant information that appears under specular reflection light and UV irradiation, and the positive image portion (11 -2) is an image expressing the second significant information as positive, and the negative image portion (12-2) is an image expressing the second significant information as negative.

  In the positive image portion (11-2), the positive image line (13-2) having an image line width of 0.16 mm is continuously arranged at a pitch of 0.5 mm in the S1 direction (direction orthogonal to the image line) in the drawing. In the negative image portion (12-2), the negative image line (14-2) having an image line width of 0.16 mm is formed in the S1 direction (perpendicular to the image line). Direction) and formed by a group of negative images arranged continuously at a pitch of 0.5 mm. The positive image line (13-2) and the negative image line (14-2) were formed by shifting the phase in the S1 direction by 0.16 mm so as not to overlap with each other in the horizontal direction and the vertical direction.

  In FIG. 19, the background image line (8-2) and the information image line (9-2) forming the first image, the positive image line (13-2) forming the second image, and The superposition positional relationship with the negative image line (14-2) is shown. First, for the first image, a gold ink containing a brass pigment, which is a glittering material having the property of absorbing UV (ultraviolet) light (New Champion Gold (Aoguchi), manufactured by Dainippon Ink & Chemicals, Inc.) is used. After forming the second image by the wet offset printing method, the second image is formed by the same wet offset printing method using an ink in which 4% of the red luminescent pigment is mixed with OP varnish (matt medium manufactured by T & K TOKA). A latent image print was formed on top of it.

  Specifically, as shown in FIGS. 17 and 18, the positive image portion (11-2) of the second image (5-2) is placed in the non-image area (10-2) of the first image (4-2). ) Forming the background image line (8-2) forming the background portion (6-2) of the first image (4-2). The negative image line (14-2) forming the negative image portion (12-2) of the image (5-2) was formed by combining the printing in a positional relationship where they overlap.

  FIG. 20 shows the effect of the latent image printed material (1-2). As shown in FIG. 20 (a), when the latent image printed matter (1-2) was observed under diffuse reflected light, the first image was visually recognized by the observer (16a-2). As shown in FIG. 20B, when the latent image printed matter (1-2) was observed under regular reflection light, the negative image portion was visually recognized by the observer (16b-2). As shown in FIG. 20 (c), when the latent image printed matter (1-2) is observed during UV irradiation by the UV light source (17-2), the positive image portion is a luminescent pigment for the observer (16c-2). It was visually recognized in red, which is the emission color. Thus, three kinds of images were visually recognized by an excellent switch effect depending on the observation state.

1, 1 ', 1-1, 1-2 Latent image printed matter 2, 2-1, 2-2 Base material 3, 3', 3-1, 3-2 Print image 4, 4 ', 4-1, 4 -2 1st image 5, 5 ', 5-1, 5-2 2nd image 6, 6-1, 6-2 Background part 7, 7-1, 7-2 Information part 8, 8-1, 8-2 Background Image Lines 9, 9-1, 9-2 Information Image Lines 10 10-1, 10-2 Non-Image Areas 11, 11-1, 11-2 Positive Image Parts 12, 12-1, 12- 2 Negative image portions 13, 13-1, 13-2 Positive image lines 14, 14-1, 14-2 Negative image lines 15, 15 ', 15-1, 15-2 Light sources 16a, 16b, 16c, 16a', 16b ', 16c', 16a-1, 16b-1, 16c-1, 16a-2, 16b-2, 16c-2 Viewer's viewpoint 17, 17 ', 17-1, 17-2 UV light source

Claims (5)

Provide a printed image on at least a part of the substrate,
The printed image includes a glittering material having a UV absorbing ability, and a second image formed of a transparent material including a luminescent material on a first image formed of a material having a color different from that of the substrate. An image is formed,
The first image has a background portion and an information portion,
The background portion is formed by a background image line group in which a plurality of background image lines are arranged in a predetermined direction at a predetermined pitch, and the information unit has a plurality of information image lines arranged in the predetermined direction at the predetermined pitch. Formed by a group of information lines,
The second image has a positive image portion and a negative image portion,
The positive image portion is formed by a group of positive image lines in which a plurality of positive image lines are arranged in the predetermined direction at the predetermined pitch, and the negative image portion has a negative image line in the predetermined direction at the predetermined pitch. It is formed by a group of negative lines arranged
The positive image line and the negative image line have different phases in the predetermined direction,
Within the predetermined pitch, either the background image line, the information image line, the positive image line or the negative image line is disposed adjacent to or in close proximity to the background image line. The other of the negative image line or the positive image line is formed so as to overlap,
In the observation angle region where diffuse reflection light is dominant, the first image is visible, and in the observation angle region where specular reflection light is dominant, the positive image or negative image of the second image is visually recognized. A latent image printed matter, wherein a negative image or a positive image of the second image is emitted and visible in a situation where the image is irradiated. The latent image printed matter according to claim 1, wherein the positive image line and the negative image line have the same image line width and are equal to or smaller than the image line width of the background image line. 3. The latent image printed matter according to claim 1, wherein the image area ratio of the first image is formed within a range of 20% to 80%. The image area ratio of the background portion in the first image is formed within a range of 20% to 60%, and the image area ratio of the information portion in the first image is the image area ratio of the background image. 4. The latent image printed matter according to claim 3, wherein the latent image printed matter is formed within a range of 10% to 40% without exceeding an area ratio. The latent image printed matter according to any one of claims 1 to 4, wherein the predetermined pitch is formed in a range of 0.1 mm to 5 mm.

Images