JP2011203615A - Recording medium and tray or paper conveyance surface shape - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a recording medium, wherein a set position is visually confirmed when setting the recording medium in a printer provided with a projecting guide.SOLUTION: The recording medium includes: a transparent resin sheet; a first lenticular lens 20 formed on one side of the transparent resin sheet; an image formation layer 22 which has a recording area 22a and non-recording area 22b and is formed on the other side of the transparent resin sheet and; and a second lenticular lens 24 which is formed on the non-recording area 22b of the image forming layer 22.

Description

  The present invention relates to a recording medium and a tray or sheet conveyance surface shape.

  2. Description of the Related Art Conventionally, a recording medium has a lenticular lens superimposed on a recording layer, and an image recorded on the recording layer can be viewed through the lenticular lens as a three-dimensional image or a change picture image that changes depending on the viewing angle. Known from. In order to be able to view an image recorded on such a recording medium as a predetermined three-dimensional image or a modified picture image, it is necessary to accurately correspond the recording position on the recording layer to the lens arrangement of the lenticular lens. is there. For this reason, for example, Patent Document 1 discloses a means for improving the conveyance angle accuracy by engaging a lens of a dedicated paper and the irregularities on the conveyance surface with a printer having the same irregularities as the lens pitch.

JP 2009-073651 A

  However, in the case of the means of Patent Document 1, there is an operation to set the dedicated paper with lens on the guide on the printer, and when the printing paper is white instead of transparent, the setting position is determined only by the sense of the hand. Therefore, there is a possibility that it is not certain whether the set position is really correct. Also, only the operator himself can determine whether it is normal. If a situation in which misalignment occurs frequently occurs, it is desirable that the alignment state is visible in order to reduce one of the causes.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following forms or application examples.

  Application Example 1 A transparent resin sheet, a first lenticular lens formed on one surface of the transparent resin sheet, a recording region and a non-recording region, and the other surface of the transparent resin sheet And a second lenticular lens formed in the non-recording area of the image forming layer.

  According to this, by adopting a double lens of the first lenticular lens and the second lenticular lens, when setting this recording medium in a printer with a convex guide, the lens effect is canceled and enlarged. Thus, it is possible to visually check whether the set position is correct. For this reason, when a parallax image is printed on the printing surface, the parallax image can be easily printed in an accurate positional relationship with the lens.

  Application Example 2 In the above recording medium, the arrangement pitch of the first lenticular lens is smaller than the arrangement pitch of the second lenticular lens.

  According to this, it is possible to easily confirm whether or not the set position is correct visually by further expanding after canceling the lens effect.

  Application Example 3 A transparent resin sheet, a first lenticular lens formed on one surface of the transparent resin sheet, an image forming layer formed on the other surface of the transparent resin sheet, A recording medium comprising: at least one folded portion that is substantially orthogonal to the arrangement of the first lenticular lenses and is thinner than other regions.

  According to this, by forming the folded portion substantially orthogonal to the lens arrangement, the recording medium can be folded from the folded portion, and the folded recording medium lens faces the printing surface side. As a result, by adopting a double lens, when setting this recording medium with a printer with a convex guide, it is possible to visually confirm whether the set position is correct by expanding after canceling the lens effect. For this reason, when a parallax image is printed on the printing surface, the parallax image can be easily printed in an accurate positional relationship with the lens.

  Here, the term “substantially orthogonal to the lens arrangement” means that, for example, in the case of a lenticular lens in which the lens is a columnar aspheric lens, it is substantially orthogonal to the longitudinal axis direction of the lenticular lens. In the case of an integral sheet provided with an eye lens, it is substantially orthogonal to a straight line connecting the centers of the eye lenses of each eyelid.

  Application Example 4 In the above recording medium, the folded portion is a notch that opens toward the first lenticular lens.

  According to this, the recording medium is easily folded from the folded portion to the other surface side on which the printing surface is formed, and the lens of the folded recording medium is easily directed to the printing surface side.

  Application Example 5 In the recording medium, the image forming layers are fixed to at least a part of a region where the image forming layers face each other by being folded from the folded portion. A recording medium provided with a fixing member.

  According to this, since the fixing member is provided in at least a part of the region, the recording medium folded from the folded portion can be easily fixed. Further, the protective sheet can be easily attached to the image forming layer.

  Application Example 6 In the above recording medium, the area where the image forming layers face each other is a non-recording area of the image forming layer.

  According to this, a printing area can be easily secured.

  Application Example 7 In the above recording medium, the fixing member is glue or a double-sided tape.

  According to this, since it is not necessary to use a special process and method by using glue or a double-sided tape as a fixing member, a recording medium can be easily manufactured.

  Application Example 8 A support surface for supporting the recording medium according to any one of the above with the first lenticular lens facing down, and a predetermined surface on the support surface with respect to the first lenticular lens. A tray or paper transport surface shape, comprising: an engaging portion of a line that engages in a transport direction; and an inspection image formed on the support surface or the engaging portion.

  According to this, by providing an inspection image on the support surface or the engagement portion, it is visually confirmed whether the set position of the lens portion on the convex surface of the recording medium and the engagement portion of the tray or paper conveyance surface shape is correct. I can judge. Further, by adopting a double lens of the first lenticular lens and the second lenticular lens, this inspection image becomes easy to see. For this reason, when a parallax image is printed on the printing surface, the parallax image can be easily printed in an accurate positional relationship with the lens.

  Application Example 9 The light source has a light diffusing means for diffusing light to the recording medium side supported by the support surface through the inspection image, with the shape of the tray or the sheet conveyance surface. Tray or paper transport surface shape.

  According to this, it is easy to see the inspection image, and it can be easily confirmed whether the set position is correct visually.

  Application Example 10 In the tray or paper transport surface shape, a plurality of the engaging portions are provided at an integral multiple of the arrangement pitch of the first lenticular lens. Surface shape.

  According to this, since a plurality of engaging portions are arranged in the main scanning direction, the engaging force between the engaging portion and the recording medium can be increased, and the movement of the recording medium in the main scanning direction is more effectively performed. Can be suppressed.

  Application Example 11 The shape of the tray or the sheet conveyance surface, wherein the inspection image is formed of a plurality of lines and a plurality of colors parallel to the engagement portion along a longitudinal direction. Tray or paper transport surface shape.

  According to this, it is visually confirmed whether or not the set position of the lens portion on the convex surface of the recording medium and the engaging portion of the tray or paper conveyance surface shape is correct due to the change in the color (moire) of the line as the inspection image. I can judge.

FIG. 3 is a rear perspective view of the recording apparatus according to the first embodiment. The enlarged view of the part R shown in FIG. FIG. 3 is a top view of the lens sheet according to the first embodiment on the image forming layer side. The figure which shows the other form of the lens sheet shown in FIG. The figure which shows the example of application of the lens sheet shown in FIG. Sectional drawing which shows the sheet | seat guide which concerns on 1st Embodiment. The figure which shows the other form of the engaging part of the sheet | seat guide shown in FIG. The figure which shows the additional function of the sheet | seat guide shown in FIG. The figure which shows the other form of the sheet | seat guide shown in FIG. The figure which shows the lens sheet of the sheet guide shown in FIG. The figure which shows the example of application of the lens sheet shown in FIG. FIG. 3 is a top view showing an inspection image according to the first embodiment. Sectional drawing which shows the other form of the test | inspection image shown in FIG. The figure which shows the visual example at the time of the setting of the sheet | seat guide which concerns on 1st Embodiment. The perspective view which shows one Embodiment of the lens sheet which concerns on 2nd Embodiment. The figure which shows the example of the glued lens sheet which concerns on 2nd Embodiment. The perspective view which shows one Embodiment of the lens sheet which concerns on 2nd Embodiment.

(First embodiment)
The recording apparatus 2 according to the first embodiment of the present invention will be described below with reference to FIGS.

  FIG. 1 is a rear perspective view of the recording apparatus according to the present embodiment. FIG. 2 is an enlarged view of a portion R shown in FIG. In FIG. 1, the direction of the arrow X, which is the direction in which the lens sheet L as a recording medium travels, is the front (front side), and the opposite direction is the rear (rear side). In addition, the direction of the arrow Y that is the right hand direction from the rear to the front is the right side (right side), and the left hand direction that is the opposite direction is the left side (left side). The following explanation will be given with the direction of the arrow Z as the upper side (upper side) and the opposite direction as the lower side (lower side).

  The recording apparatus 2 includes a housing 10 that is an exterior body, a sheet guide 12 that is a tray or a sheet conveyance surface shape that supports a lens sheet L as a recording medium from below, and a lens that is placed on the sheet guide 12. A sheet feed roller 14 and a sheet discharge roller 16 that convey the sheet L from the rear to the front, a recording head 18 that performs recording on the lens sheet L, and the like.

  The lens sheet L includes a transparent resin sheet, a first lenticular lens 20 formed on one surface of the transparent resin sheet, a recording area 22a and a non-recording area 22b (see FIG. 3), and is transparent. An image forming layer 22 formed on the other surface of the resin sheet and a second lenticular lens 24 formed in the non-recording area 22b of the image forming layer 22 are provided.

  In the lens sheet L, the first lenticular lens 20 is formed on one surface of a transparent resin sheet, and the image forming layer 22 is formed on the other surface. The lens sheet L is configured so that an image recorded on the image forming layer 22 can be viewed through the first lenticular lens 20. Therefore, for example, when an image having a parallax is recorded on the image forming layer 22 in correspondence with the arrangement pitch, the focal length, and the like of the first lenticular lens 20, the image is viewed from the first lenticular lens 20 side. In other words, the image can be viewed as a three-dimensional image or as a different image depending on the viewing angle. The lens sheet L may be configured to directly record on the resin portion on the surface opposite to the side on which the first lenticular lens 20 is formed without forming the image forming layer 22.

  A paper feed opening 26 for supplying the lens sheet L into the housing 10 is formed on the rear side surface of the housing 10, and the paper supply opening 26 is supplied on the front side surface from the paper feed opening 26 side. A paper discharge opening 28 for discharging the lens sheet L is formed. The lens sheet L supplied to the recording apparatus 2 from the paper feed opening 26 is conveyed forward by the paper feed roller 14 and the paper discharge roller 16 and is recorded by the recording head 18 and then discharged. The ink is discharged from the opening 28 to the outside of the recording apparatus 2.

  The sheet guide 12 is disposed below the paper feed roller 14 and the paper discharge roller 16 and has a rectangular plate-like body as a whole. The sheet guide 12 is provided in the front-rear direction from a position protruding rearward of the paper feed opening 26 to a position between the paper discharge opening 28 and the paper discharge roller 16. Moreover, about the width direction on either side, it is the width | variety which can be supported over the full width of the lens sheet L mounted. The seat guide 12 is attached to the housing 10 or a structure such as an internal frame with a configuration not shown.

  The sheet guide 12 includes a plate-shaped substrate 30 formed of a resin, an upper surface 30A as a support surface that supports the lens sheet L with the first lenticular lens 20 facing down, and a first surface on the upper surface 30A. A linear engagement portion 32 that engages with the lenticular lens 20 in a predetermined conveyance direction, and an inspection image 34 (see FIG. 5) formed on the upper surface 30A or the engagement portion 32. I have. The engaging portion 32 is provided on the upper surface 30 </ b> A that is the surface of the substrate 30 that supports the lens sheet L, and is formed in the same shape as the first lenticular lens 20. That is, the convex ridges 38 having the same shape as the lens elements 36 (for example, cylindrical lenses) forming the first lenticular lens 20 have the same pitch as the arrangement pitch of the first lenticular lens 20 and the lens sheet L. They are arranged side by side over a width wider than the width. The longitudinal direction of the ridge 38, that is, the generatrix (ridgeline) direction of the ridge 38 is formed along a predetermined conveyance direction of the lens sheet L, that is, a direction orthogonal to the sheet feed roller 14 and the sheet discharge roller 16.

  A plurality of engaging portions 32 may be provided at an integral multiple of the arrangement pitch of the first lenticular lens 20. As a result, since a plurality of engaging portions 32 are arranged in the main scanning direction, the engaging force between the engaging portion 32 and the lens sheet L can be increased, and the movement of the lens sheet L in the main scanning direction is more effective. Can be suppressed.

  In the present embodiment, the engaging portion 32 is formed of the same member as the first lenticular lens 20. That is, by attaching the lens sheet L with the convex surface of the first lenticular lens 20 facing upward to the upper surface of the substrate 30, the engagement portion 32 is provided on the substrate 30. Thus, by forming the engaging portion 32 with the lens sheet L, the engaging portion 32 can be easily provided on the substrate 30. When the substrate 30 is formed by resin molding, a mold surface corresponding to the engaging portion 32 may be formed in advance on the molding die, and the engaging portion 32 may be formed integrally with the substrate 30. . When the engaging portion 32 is integrally molded with the substrate 30 as described above, the lens sheet L and the engaging portion 32 are formed by using a resin material forming the substrate 30 as a low-friction resin material such as fluororesin. And the lens sheet L can be transported smoothly. Further, the substrate 30 may be formed of a metal plate. In this case, the engaging portion 32 can be formed by cutting the metal plate.

  Thereby, by providing the inspection image 34 on the upper surface 30A or the engaging portion 32, it is visually determined whether or not the set position of the first lenticular lens 20 of the lens sheet L and the engaging portion 32 of the sheet guide 12 is correct. it can. In addition, by adopting a double lens of the first lenticular lens 20 and the second lenticular lens 24, the inspection image 34 can be easily seen. For this reason, when a parallax image is printed on the printing surface, the parallax image can be easily printed in an accurate positional relationship with the lens.

  In the first and second lenticular lenses 20 and 24, a plurality of semi-cylindrical or arc-shaped elongated convex portions are arranged in parallel. The first and second lenticular lenses 20 and 24 are each formed with a plurality of columnar aspheric lenses (cylindrical lenses). The first and second lenticular lenses 20 and 24 are arranged in parallel at equal intervals in the longitudinal axis direction.

  A paper feed roller 14 and a paper discharge roller 16 are disposed before and after the recording head 18. The paper feed roller 14 and the paper discharge roller 16 are rotationally driven by a paper feed motor 42 and a paper discharge motor 44, respectively, and the lens sheet L placed on the sheet guide 12 is directed from the rear to the front. Transport.

  The recording head 18 is attached to the lower surface of the carriage 46, and in this embodiment, is configured as an ink jet recording head that ejects ink. The carriage 46 is movably supported by a carriage guide 48 that extends in the left-right direction, and is attached to a timing belt 52 that is driven by a carriage motor 50. Therefore, when the timing belt 52 is rotationally driven in the left-right direction by the carriage motor 50, the recording head 18 can move in the left-right direction along the carriage guide 48 together with the carriage 46.

  Therefore, the feeding of the lens sheet L in the sub-scanning direction, which is the feeding direction of the lens sheet L, by the paper feed roller 14 and the paper discharge roller 16 is controlled, and the recording head 18 is moved in the main scanning direction, that is, in the left-right direction. Also, the recording head 18 can be moved to a predetermined position on the lens sheet L, and an image can be recorded at a desired position on the lens sheet L. The lens sheet L is placed on the sheet guide 12 so that the image forming layer 22 side faces the recording head 18 and the first lenticular lens 20 side contacts the engaging portion 32. That is, the recording head 18 performs recording on the image forming layer 22, and a recorded matter is produced in which the image recorded on the image forming layer 22 can be viewed from the first lenticular lens 20 side. .

  As described above, when recording is performed on the lens sheet L by the recording apparatus 2 configured, the lens sheet L is directed toward the engaging portion 32 of the sheet guide 12 with the first lenticular lens 20 side. Place on the sheet guide 12. At this time, whether the set position is correct or not is visually confirmed using the inspection image 34 of the sheet guide 12 with the double lens of the first lenticular lens 20 and the second lenticular lens 24. Since the engaging portion 32 and the first lenticular lens 20 have the same shape, the lens sheet L placed on the sheet guide 12 is a lens constituting the first lenticular lens 20 as shown in FIG. The element 36 and the ridge 38 are engaged with each other, and the lens sheet L is positioned in the left-right direction (main scanning direction) by the engaging portion 32. Further, the ridge 38 is formed so that the generatrix (ridgeline) direction thereof is along a direction orthogonal to the main scanning direction which is a predetermined conveyance direction of the lens sheet L. Therefore, when the lens sheet L is transported by the paper feed roller 14 and the paper discharge roller 16, it is transported while being guided in a direction orthogonal to the main scanning direction by the engaging portion 32. That is, the sheet guide 12 is arranged so that the generatrix (ridgeline) direction of the ridges 38, that is, the guide direction of the engaging portion 32 is along the predetermined conveyance direction of the lens sheet L. It is transported in a state where the transport direction is kept constant. When the lens sheet L is transported in a state where the transport direction is maintained constant, recording on the lens sheet L by the recording head 18 can be performed at a predetermined position.

  The interval between the sheet feeding roller 14 and the sheet guide 12 and the interval between the sheet discharge roller 16 and the sheet guide 12 are intervals at which an appropriate pressing force can be applied to the lens sheet L from these rollers. Yes. That is, by pressing the lens sheet L against the sheet guide 12, the engagement between the engaging portion 32 and the first lenticular lens 20 can be ensured, and the lens sheet L is conveyed. The conveyance accuracy in the left-right direction, that is, the straightness of conveyance of the lens sheet L can be improved.

  In particular, for example, when the lens sheet L is curved in the vertical direction, the engagement between the first lenticular lens 20 and the engaging portion 32 is easily released. Therefore, the first lenticular lens is pressed by pressing the lens sheet L against the sheet guide 12 by the paper feed roller 14 and the paper discharge roller 16 so that the curved first lenticular lens 20 is not separated from the sheet guide 12. 20 and the engaging part 32 can be kept engaged. On the other hand, when the lens sheet L is pressed against the sheet guide 12 with a strong force, a conveyance load such as friction between the lens sheet L and the sheet guide 12 increases, and the lens sheet L cannot be smoothly conveyed. Therefore, an appropriate pressing force is applied so that the engagement state between the first lenticular lens 20 and the engagement portion 32 can be reliably maintained while considering the conveyance load so that the lens sheet L can be smoothly conveyed. The interval between the sheet feeding roller 14 and the sheet guide 12 and the interval between the sheet discharge roller 16 and the sheet guide 12 are set.

  For example, in this embodiment, the surface of the paper feed roller 14 and the paper discharge roller 16 can be elastically deformed by covering the periphery of the paper feed roller 14 and the paper discharge roller 16 with a thick rubber material having elasticity. In addition, by configuring the distance between the paper feed roller 14 and the sheet guide 12 and the distance between the paper discharge roller 16 and the sheet guide 12 to be smaller than the thickness of the lens sheet L, the paper feed roller 14 and the paper discharge roller 16 can be The lens sheet L is pressed against the sheet guide 12. With this configuration, when the lens sheet L passes between the paper feed roller 14 and the paper discharge roller 16 and the sheet guide 12, the contact of the paper feed roller 14 and the paper discharge roller 16 with the lens sheet L is achieved. The surface of the part is elastically deformed flat. The lens sheet L is conveyed by the rotation of the paper feed roller 14 and the paper discharge roller 16 while being pressed against the sheet guide 12 by the reaction force of the elastic deformation. By appropriately setting the elasticity and thickness of the rubber material, as well as the distance between the paper feed roller 14 and the sheet guide 12 and the distance between the paper discharge roller 16 and the sheet guide 12, the lens sheet L can be made smooth. While being able to be conveyed, the first lenticular lens 20 can be pressed against the engaging portion 32 with an appropriate pressing force.

  If the surfaces of the paper feed roller 14 and the paper discharge roller 16 are configured to be elastically deformable as described above, the distance between the paper feed roller 14 and the paper discharge roller 16 and the sheet guide 12 is set to a so-called copy paper. The lens sheet L can be conveyed while applying the above-described pressing force while setting the interval at which the paper medium such as can be conveyed.

  While the thickness of a paper medium such as copy paper is about 0.1 mm, the lens sheet L needs to form the first lenticular lens 20, so that the thickness is about 0.5 mm. It has become. Therefore, by setting the interval to a narrow interval that can transport the paper medium, the paper medium can be transported when the transport target is a paper medium. On the other hand, when the object to be conveyed is a thick lens sheet L, the contact portion of the paper feed roller 14 and the paper discharge roller 16 with the lens sheet L is elastically deformed, and the lens sheet L is elastically deformed to the sheet guide 12 by the rubber material. It can be transported while being pressed by a reaction force.

  The paper feed roller 14 and the paper discharge roller 16 are longer than the left and right widths of the lens sheet L. Therefore, the lens sheet L can be uniformly pressed against the engaging portion 32 over a wide range, and the engagement state between the first lenticular lens 20 and the engaging portion 32 can be made more reliable. .

  FIG. 3 is a top view of the lens sheet L according to the present embodiment on the image forming layer 22 side. The recording area 22a of the image forming layer 22 of the lens sheet L is white, and the non-recording area 22b is transparent. The lens sheet L includes a lens for checking the inspection image 34 in the non-recording area 22b. The recording area 22a may be transparent.

  FIG. 4 is a diagram showing another form of the lens sheet L shown in FIG. FIG. 5 is a diagram showing an application example of the lens sheet L shown in FIG.

  The first lenticular lens 20 and the second lenticular lens 24 of the lens sheet L are overlapped to constitute a double lens for confirming the inspection image 34. As a result, the effect of enlarging the image is increased, so that the inspection image 34 is considerably easier to see. The double lens configuration of the lens sheet L (transparent portion for confirming the inspection image 34) may be provided on all four sides of the lens sheet L or may be a part of the four sides. The lens sheet L may be provided with perforations so that the double lens component can be separated.

  The lengths of the first lenticular lens 20 and the second lenticular lens 24 of the lens sheet L may be the same (FIG. 4A) or may be different (FIG. 4B). Further, the number may be the same (FIG. 4B) or different (FIG. 4C). For example, the number of the second lenticular lens 24 may be one or more.

  The arrangement pitch of the first lenticular lenses 20 on the lens sheet L and the arrangement pitch of the second lenticular lenses 24 may be the same or different (FIG. 4D). For example, the arrangement pitch of the first lenticular lens 20 may be smaller than the arrangement pitch of the second lenticular lens 24. Thereby, it is possible to easily confirm whether the set position is correct visually by further expanding after canceling the lens effect.

  The lens sheet L may have a configuration in which a lenticular lens is coated with an ink receiving layer (ink absorption layer, ink transmission layer). The lens sheet L may have a configuration in which a backlight film (PET layer, ink transmission layer, ink absorption layer) is laminated to a lenticular lens with a double-sided tape. As shown in FIG. 5, the lens sheet L is placed on the sheet guide 12, and the lens elements 36 and the ridges 38 constituting the first lenticular lens 20 are engaged with each other, and the lens sheet L is engaged with the engaging portion 32. Thus, the positioning in the left-right direction (main scanning direction) is performed.

  FIG. 6 is a cross-sectional view showing the sheet guide 12 according to the present embodiment. The sheet guide 12 includes a plate-shaped substrate 30 formed of a resin, an upper surface 30A as a support surface that supports the lens sheet L with the first lenticular lens 20 facing down, and a first surface on the upper surface 30A. The lenticular lens 20 includes a linear engagement portion 32 that engages along a predetermined conveyance direction, and an inspection image 34 formed on the upper surface 30A or the engagement portion 32.

  FIG. 7 is a view showing another form of the engaging portion 32 of the sheet guide 12 shown in FIG. The engaging portion 32 of the sheet guide 12 may have a plurality of convex shapes, or may have a single convex shape as shown in FIG.

  FIG. 8 is a diagram showing an additional function of the sheet guide 12 shown in FIG. The sheet guide 12 may include a light source layer 62 as a light diffusing unit that diffuses light to the lens sheet L side supported by the upper surface 30 </ b> A via the inspection image 34. Thereby, it becomes easy to see the inspection image 34 and it can be easily confirmed whether the set position is correct visually.

  FIG. 9 is a view showing another form of the sheet guide 12 shown in FIG. The inspection image 34 of the sheet guide 12 may be on the engaging portion 32 as shown in FIG. 9A or on the upper surface 30A as shown in FIG. 9B.

  FIG. 10 is a diagram showing the lens sheet L of the sheet guide 12 shown in FIG. FIG. 11 is a diagram illustrating an application example of the lens sheet L illustrated in FIG. 10. The directions of the opposing lenses of the first lenticular lens 20 and the second lenticular lens 24 of the lens sheet L may be the same or different. For example, as shown in FIG. 10, the lens sheet L may have different facing lens orientations between the first lenticular lens 20 and the second lenticular lens 24. As shown in FIG. 11, the lens sheet L is placed on the sheet guide 12, and the lens elements 36 and the ridges 38 constituting the first lenticular lens 20 are engaged with each other, and the lens sheet L is engaged with the engaging portion 32. Thus, the positioning in the left-right direction (main scanning direction) is performed.

  FIG. 12 is a top view showing the inspection image 34 according to the present embodiment. FIG. 13 is a cross-sectional view showing another form of the inspection image 34 shown in FIG. As shown in FIG. 12, the inspection image 34 of the sheet guide 12 has an inspection line 40 parallel to the longitudinal direction of the ridges 38 on the upper surface 30A or the engaging portion 32, that is, along the generatrix (ridgeline) direction of the ridges 38. It may be. The inspection line 40 may be one or more lines with respect to one convex shape of the ridge 38 on the engaging portion 32 (FIG. 13A). Moreover, one or more lines may be sufficient with respect to the two convex shapes of the protruding item | line 38 on the engaging part 32 (FIG.13 (B)). Furthermore, it may be one or more lines for one convex shape of the convex strip 38 on the engaging portion 32 (FIG. 13C). Thereby, it is possible to visually determine whether or not the set position of the first lenticular lens 20 of the lens sheet L and the engaging portion 32 of the sheet guide 12 is correct by the change in the color (moire) of the line as the inspection image 34. .

  The inspection line 40 may be a line formed by a real line such as a metal line. For example, a physical wire such as a metal wire, a resin wire, a fiber wire, or a wire made of protein may be used. The line width is better if it is at least twice the lens resolution. At the time of installation, it can be easily installed by using a valley between the convex portions of the engaging portion 32.

  In addition, the inspection image 34 and the printing surface (the upper surface 30A or the engaging portion 32) of the inspection image 34 have a color difference such as a blue and white group or a red and blue group in order to improve the visibility. It may be provided.

  Furthermore, the inspection image 34 may be a parallax image in which the image is switched depending on the viewing position (the pattern changes depending on the viewer). The inspection image 34 may be mechanically replaced. The inspection image 34 may be an image in which a moire state is easy to see.

  FIG. 14 is a view showing a visual example when the sheet guide 12 according to the present embodiment is set. When the lens sheet L is not displaced with respect to the sheet guide 12, as shown in FIG. 14A, the inspection line 40 has one line or no line, and the lens sheet L is not displaced with respect to the sheet guide 12. In a certain state, as shown in FIG. 14B, two or more lines are confirmed.

  In the observation of the inspection image 34 in the present embodiment, the moire state is easy to see in the order of FIG. 9, FIG. 6, FIG. 5, FIG.

  According to the present embodiment, when the lens sheet L is set in the recording apparatus 2 by adopting a double lens of the first lenticular lens 20 and the second lenticular lens 24, the lens effect is offset, By enlarging, it can be visually confirmed whether the set position is correct. For this reason, when a parallax image is printed on the printing surface, the parallax image can be easily printed in an accurate positional relationship with the lens.

  In the embodiment described above, the lens sheet L provided with the first lenticular lens 20 has been described. However, the lens sheet L is not limited to the lens sheet L, and the eyelet lens is provided. The present invention can be applied to a lens sheet using various other lenses such as an integral sheet.

(Second Embodiment)
FIG. 15 is a perspective view showing an embodiment of the lens sheet M according to this embodiment. FIG. 16 is a diagram illustrating an example of the glued lens sheet M according to the present embodiment. As shown in FIG. 15, the lens sheet M as a recording medium has a plurality of first lenticular lenses 20 that are columnar aspherical lenses (cylindrical lenses) formed on one surface and ink absorption on the other surface. An image forming layer 22 composed of layers is formed. The first lenticular lenses 20 are arranged in parallel at equal intervals in the longitudinal axis direction (the direction of arrow A in FIG. 15).

  The lens sheet M includes a transparent resin sheet, a first lenticular lens 20 formed on one surface of the transparent resin sheet, an image forming layer 22 formed on the other surface of the transparent resin sheet, And at least one folded portion 54 that is substantially orthogonal to the arrangement of the lenticular lenses 20 and that is thinner than other regions.

  The folding | returning part 54 may be the notch opened toward the 1st lenticular lens 20 side. Accordingly, the lens sheet M is easily folded from the folded portion 54 to the other surface side where the image forming layer 22 is formed, and the lens of the folded lens sheet M is easily directed to the image forming layer 22 side. The area where the image forming layers 22 face each other may be a non-recording area 22 b of the image forming layer 22. As a result, the print area can be easily secured.

  A fixing member 56 that fixes the image forming layers 22 to each other may be provided in at least a part of a region of the image forming layers 22 that are turned back from the turn-back portion 54 and face each other. Thereby, since the fixing member 56 is provided in at least a part of the region, the lens sheet M folded back from the folded portion 54 can be easily fixed. Further, the protective sheet can be easily attached to the image forming layer 22. The fixing member 56 may be glue or double-sided tape. The fixing member 56 may include a transparent adhesive layer and a release paper. The transparent adhesive layer may be a re-peeling adhesive. This makes it possible to fold back and so on, which is optimal when a double lens configuration is adopted. Further, it is further preferable that the re-peeling adhesive is bonded only once. Furthermore, since it is not necessary to use a special process and method by using glue or a double-sided tape as the fixing member 56, the lens sheet M can be easily manufactured.

  The lens sheet M is obtained by bending a part of the first lenticular lens 20 (FIG. 16A), and the bent part may be the second lenticular lens 24 (FIG. 16B). The first lenticular lens 20 and the second lenticular lens 24 may overlap to form a double lens for confirming the inspection image 34. The double lens of the lens sheet M may be connected to the paper during printing. However, it is preferable that the lens is separated or flattened in order to shorten the platen distance (FIG. 16C). Good.

  The lens sheet M is formed with a folded portion 54 that is a notch that opens toward the first lenticular lens 20, and the folded portion 54 is substantially in the longitudinal axis direction of the first lenticular lens 20. It is formed so as to extend in an orthogonal direction (the direction of arrow B in FIG. 15). The lens sheet M is divided into an observation lenticular sheet 58 in the central recording area 22a and a detection lenticular sheet 60 in the non-recording area 22b on the end side by a single folded portion 54. Therefore, the shape, arrangement position, and arrangement pitch of the first lenticular lens 20 in the observation lenticular sheet 58 and the detection lenticular sheet 60 are exactly the same. One folded portion 54 may be formed as described above, or two or more folded portions 54 may be formed. In this case, the area of the detection lenticular sheet 60 can be widened, and the region for confirming the set position with respect to the lens sheet M can be widened.

  FIG. 17 is a perspective view showing an embodiment of the lens sheet M according to this embodiment. 17A is a perspective view of the lens sheet M folded from the folded portion 54, and FIG. 17B is a perspective view of the lens sheet M folded from the folded portion 54 as viewed from the back side. . Since the folded portion 54 is opened toward the first lenticular lens 20 side, the detection lenticular sheet 60 is for observation as shown in FIGS. 17A and 17B with the folded portion 54 as a fulcrum. The lenticular sheet 58 can wrap around to the image forming layer 22 side.

  As described above, the detection lenticular sheet 60 may only be able to wrap around the image forming layer 22 side of the observation lenticular sheet 58, or the detection lenticular sheet 60 and the image forming layer 22 of the observation lenticular sheet 58 may be provided. An adhesive such as glue or a double-sided tape (fixing member 56) may be provided on at least a part of the overlapping region, and the wrapped detection lenticular sheet 60 may be attached to the image forming layer 22 of the observation lenticular sheet 58. .

  Next, the operation of the lens sheet M having the above configuration will be described. The printing on the lens sheet M described above is performed based on the following procedure. First, as shown in FIGS. 17A and 17B, the lens sheet M is formed by bending the detection lenticular sheet 60 toward the image forming layer 22 side of the observation lenticular sheet 58 to form the image forming layer of the observation lenticular sheet 58. In a state where 22 is directed upward, it is set in the recording apparatus 2 using, for example, an ink jet method. At this time, whether the set position is correct or not is visually confirmed using the inspection image 34 of the sheet guide 12 with the double lens of the first lenticular lens 20 and the second lenticular lens 24. Thereafter, the printing operation is performed in the same manner as in the first embodiment.

  According to the above configuration, since the shape of the surface on which the image forming layer 22 is formed is a flat shape, for example, a sheet (protective sheet) for protecting the parallax image printed on the image forming layer 22 is used. It can be made easier to paste. Further, since the image forming layer 22 is planar, it is not necessary to use a special process or method to form the image forming layer 22 and can be easily formed. Therefore, the lens sheet M having the image forming layer 22 can be easily manufactured.

  By forming the folded portion 54 substantially orthogonal to the arrangement of the first lenticular lenses 20, the detection lenticular sheet 60 can be folded from the folded portion 54, and the first lenticular sheet of the folded detection lenticular sheet 60 can be obtained. The lens 20 faces the image forming layer 22 side of the observation lenticular sheet 58. As a result, the position of the parallax image to be printed on the image forming layer 22 can be determined based on the arrangement position and arrangement pitch of the first lenticular lens 20 on the detection lenticular sheet 60, and the parallax image can be determined as the first lenticular lens. 20 can be printed in an accurate positional relationship.

  According to this embodiment, the lens sheet M can be folded from the folded portion 54 by forming the folded portion 54 that is substantially orthogonal to the lens arrangement, and the lens of the folded lens sheet M is the image forming layer 22. It will turn to the side. As a result, by adopting a double lens, when this lens sheet M is set in the recording apparatus 2 with a convex guide, it is visually confirmed whether the set position is correct by expanding after canceling the lens effect. it can. For this reason, when a parallax image is printed on the printing surface, the parallax image can be easily printed in an accurate positional relationship with the lens.

  DESCRIPTION OF SYMBOLS 2 ... Recording apparatus 10 ... Housing | casing 12 ... Sheet guide (Tray or paper conveyance surface shape) 14 ... Paper feed roller 16 ... Paper discharge roller 18 ... Recording head 20 ... 1st lenticular lens 22 ... Image formation layer 22a ... Recording area 22b ... non-recording area 24 ... second lenticular lens 26 ... feeding opening 28 ... discharge opening 30 ... substrate (resin sheet) 30A ... upper surface (supporting surface) 32 ... engaging portion 34 ... inspection image 36 ... lens Element 38 ... Projection 40 ... Inspection line 42 ... Paper feed motor 44 ... Paper discharge motor 46 ... Carriage 48 ... Carriage guide 50 ... Carriage motor 52 ... Timing belt 54 ... Folding part 56 ... Fixing member 58 ... Observation lenticular Sheet 60 ... Detection lenticular sheet 62 ... Light source layer (light diffusion means) L: Lens sheet (recording medium).

Claims (11)

A transparent resin sheet,
A first lenticular lens formed on one surface of the transparent resin sheet;
An image forming layer having a recording area and a non-recording area and formed on the other surface of the transparent resin sheet;
A second lenticular lens formed in the non-recording area of the image forming layer;
A recording medium comprising: The recording medium according to claim 1,
A recording medium, wherein an arrangement pitch of the first lenticular lens is smaller than an arrangement pitch of the second lenticular lens. A transparent resin sheet,
A first lenticular lens formed on one surface of the transparent resin sheet;
An image forming layer formed on the other surface of the transparent resin sheet;
At least one folded portion that is substantially orthogonal to the arrangement of the first lenticular lenses and has a thickness that is thinner than other regions;
A recording medium comprising: The recording medium according to claim 3,
The recording medium according to claim 1, wherein the folded portion is a cut that opens toward the first lenticular lens. The recording medium according to claim 3 or 4,
A fixing member for fixing the image forming layers to each other is provided in at least a part of a region of the image forming layers facing each other when folded from the folded portion. recoding media. In the recording medium according to any one of claims 3 to 5,
An area where the image forming layers face each other is a non-recording area of the image forming layer. In the recording medium according to any one of claims 3 to 6,
The recording medium, wherein the fixing member is glue or double-sided tape. A support surface for supporting the recording medium according to any one of claims 1 to 7 with its first lenticular lens facing down;
An engaging portion of a line that engages the first lenticular lens on the support surface along a predetermined conveyance direction;
An inspection image formed on the support surface or the engagement portion;
A tray or paper conveyance surface shape characterized by including: In the tray or paper conveyance surface shape according to claim 8,
A tray or paper conveyance surface shape characterized by having light diffusion means for diffusing light toward the recording medium supported by the support surface via the inspection image. In the tray or paper conveyance surface shape according to claim 8 or 9,
A plurality of the engaging portions are provided at an integral multiple of the arrangement pitch of the first lenticular lens. In the tray or paper conveyance surface shape as described in any one of Claims 8-10,
The inspection image is formed of a plurality of lines and a plurality of color lines parallel to the engaging portion along the longitudinal direction.