JP5402147B2 - Supply cassette, recording apparatus, and supply method - Google Patents

Description

  The present invention relates to a supply cassette, a recording apparatus, and a supply method.

  It is known that by arranging an image on the back side of the lenticular lens, a stereoscopic image or an image whose pattern changes according to the viewing angle can be obtained. When obtaining such an image, the image may be pasted on the back of the lenticular lens, but an image is also directly recorded on the back of the lenticular lens.

  The image on the back side of the lenticular lens (lenticular image) needs to be accurately matched to the lens arrangement of the lenticular lens. Therefore, even when an image is recorded on the back surface of the lenticular lens, it is necessary to align the lenticular lens and the image with high accuracy.

  Patent Document 1 discloses a technique for detecting the position of a lenticular lens using a sensor and recording at a predetermined position based on the detection result. Japanese Patent Application Laid-Open No. 2004-228561 discloses a technique for improving the accuracy of the recording position by taking measures to prevent the recording medium placed on the transfer tray from being displaced on the tray.

Japanese Patent No. 3471930 JP 2007-130769 A

In Patent Document 1, since a sensor for detecting the position of the lenticular lens is required, the cost of the apparatus increases. Further, in Patent Document 2, even if the positional deviation of the recording medium with respect to the conveyance tray can be suppressed, if the conveyance tray is conveyed in a state inclined with respect to the conveyance direction, the accuracy of the image recording position on the recording medium decreases. To do.
An object of the present invention is to improve the recording position accuracy with a simple configuration.

The main invention for achieving the object is as follows:
A supply cassette for supplying a recording medium having a lenticular lens to a recording apparatus,
A guide unit for supporting the recording medium and guiding the recording medium along a generatrix direction of the lenticular lens;
An outer frame that covers the guide unit while forming an insertion port for inserting the recording medium and a supply port for supplying the recording medium inserted from the insertion port to the recording apparatus, and is opposed to the guide unit An outer frame having a slit formed along the generatrix direction at a position to be
A pressing member for pressing the recording medium against the guide through the slit;
Is a supply cassette.
Other features of the present invention will become apparent from the description of the present specification and the accompanying drawings.

FIG. 1A is an enlarged cross-sectional view of a lens sheet. FIG. 1B is a view of the lens sheet as viewed from the lenticular lens side. FIG. 1C is an explanatory diagram of another lens sheet. FIG. 2 is a block diagram for explaining a schematic configuration of a recording apparatus. It is the perspective view which looked at the recording device from back. FIG. 4 is an enlarged view of a portion R shown in FIG. 3. FIG. 5A is a top view of the lens sheet placed obliquely with respect to the guide. 5B is a cross-sectional view taken along line AA in FIG. 5A. 5C is a cross-sectional view taken along line BB in FIG. 5A. FIG. 10 is a diagram illustrating a relationship between a supply cassette 200 and a recording apparatus 100 in a modified example. FIG. 7A is an explanatory diagram of a cross-sectional shape of the engaging portion of the guide of FIG. FIG. 7B is an explanatory diagram of a cross-sectional shape of the engaging portion according to the first modification. FIG. 7C is an explanatory diagram of a cross-sectional shape of the engaging portion of the second modified example. FIG. 7D is an explanatory diagram of a cross-sectional shape of an engaging portion according to a fourth modified example. FIG. 7E is an explanatory diagram of a cross-sectional shape of an engaging portion according to a fourth modification. FIG. 8A is an explanatory diagram of an end face on the upstream side in the conveyance direction of the guide of FIG. 3. FIG. 8B is an explanatory diagram of a modification of the end face shape of the guide. FIG. 9A is an explanatory diagram of the end shape of the engaging portion of the guide of FIG. 9B to 9E are modifications of the end shape of the convex portion of the engaging portion. It is the figure which looked at a part of guide of the modification from the top. FIG. 11A is an explanatory diagram of a first modification of the number of convex portions. FIG. 11B is an explanatory diagram of a second modification of the number of convex portions. FIG. 11C is an explanatory diagram of a third modification of the number of convex portions. FIG. 11D is an explanatory diagram of a fourth modification of the number of convex portions. It is explanatory drawing of the image for a test | inspection. It is explanatory drawing of the image for a test | inspection seen from the lenticular lens side. It is a figure explaining the supply cassette 200 in this embodiment. It is a figure explaining supply cassette 200 'of the 1st modification. It is a figure explaining supply cassette 200 '' of the 2nd modification. It is a figure explaining supply cassette 200 '' '' of the 3rd modification.

  At least the following matters will become clear from the description of the present specification and the accompanying drawings.

A supply cassette for supplying a recording medium having a lenticular lens to a recording apparatus,
A guide unit for supporting the recording medium and guiding the recording medium along a generatrix direction of the lenticular lens;
An outer frame that covers the guide unit while forming an insertion port for inserting the recording medium and a supply port for supplying the recording medium inserted from the insertion port to the recording apparatus, and is opposed to the guide unit An outer frame having a slit formed along the predetermined direction at a position to be
Supply cassette comprising.
In this way, the recording position accuracy can be increased with a simple configuration.

  In this supply cassette, it is desirable that the interval from the insertion port to the supply port is longer than the length in the bus-line direction of the recording medium of a standard size that can be inserted into the insertion port. Moreover, it is preferable that the slit is provided in a central portion of the outer frame. The slit may be provided at an end of the outer frame in a direction that intersects the generatrix direction. The slit may be formed by cutting from the insertion hole of the recording medium in the outer frame.

Furthermore, it is good also as providing the pressing member for pressing the said recording medium to the said guide part through the said slit. The slit preferably includes a guide for sliding the pressing member in the predetermined direction. Moreover, it is desirable that the guide part has a convex part formed along the predetermined direction.
In this way, the recording position accuracy can be increased with a simple configuration.

(A) a guide unit for supporting a recording medium having a lenticular lens and guiding the recording medium along a generatrix direction of the lenticular lens;
An outer frame that covers the guide unit while forming an insertion port for inserting the recording medium and a supply port for supplying the recording medium inserted from the insertion port to the recording apparatus, and is opposed to the guide unit An outer frame having a slit formed along the predetermined direction at a position to be
A supply cassette comprising:
(B) a head that ejects liquid onto the recording medium supplied from the supply port;
A recording apparatus comprising:
In this way, the recording position accuracy can be increased with a simple configuration.

Inserting a recording medium having a lenticular lens into the insertion slot of the supply cassette;
Conveying the recording medium to a supply port facing the insertion port while pressing the lenticular lens against the guide part from a slit formed in the supply cassette;
Discharging the recording medium from the supply port along the generatrix direction;
Including a supply method.
In this way, the recording position accuracy can be increased with a simple configuration.

=== Lens sheet ===
First, a lens sheet that is a recording medium having a lenticular lens will be described.
FIG. 1A is an enlarged cross-sectional view of a lens sheet. FIG. 1B is a view of the lens sheet as viewed from the lenticular lens side. FIG. 1C is an explanatory diagram of another lens sheet.

The lens sheet L includes a lenticular lens 7 and an image forming layer 8.
The lenticular lens 7 is a resin optical member (cylindrical lens array) in which a large number of cylindrical lenses 13 are arranged in the sheet surface direction. In the following description, the generatrix direction of the cylindrical lens 13 is referred to as “x direction”, and the direction in which the cylindrical lenses 13 are arranged is referred to as “y direction” (x and y are lowercase letters). In addition, the most protruding portion (peak) of each cylindrical lens 13 may be referred to as a “mountain”, a concave portion between the cylindrical lenses may be referred to as a “valley”, and a continuous line of peaks may be referred to as a “ridge line”.

  The image forming layer 8 includes an ink transmission layer 8A and an ink absorption layer 8B. The ink transmission layer 8A is located outside the lens sheet L, and the ink absorption layer 8B is located between the ink transmission layer 8A and the lenticular lens 7. When an image is recorded by the inkjet recording method from the image forming layer 8 side of the lens sheet L, the ink passes through the ink transmission layer 8A and is absorbed by the ink absorption layer 8B, and the image can be visually recognized through the lenticular lens 7.

  The image forming layer 8 of the lens sheet L may be omitted. For example, if an ultraviolet curable ink is used, an image can be recorded directly on the back surface of the lenticular lens 7 without the ink transmission layer 8A and the ink absorption layer 8B.

  The recording apparatus of this embodiment described below conveys the lens sheet L along the generatrix direction (x direction) of the lenticular lens 7 using the shape of the lenticular lens 7. Specifically, a convex portion is formed on a guide (described later) along the conveyance direction, and the lens sheet L is slid and conveyed while the valley between the cylindrical lenses is engaged with the convex portion. The conveying direction of the recording apparatus and the generatrix direction (x direction) of the lens are made to coincide.

  As a result, each cylindrical lens 13 of the lenticular lens 7 is positioned at a predetermined position at the recording position of the recording apparatus (position where the head ejects ink to form an image). As a result, an image can be recorded with high accuracy in accordance with the lens arrangement of the lenticular lens 7.

  In FIG. 1B, the direction of the side of the lens sheet L coincides with the x direction and the y direction. However, as shown in FIG. 1C, the direction of the side of the lens sheet L may not match the x direction or the y direction depending on the type of the lens sheet L or the manufacturing accuracy of the lens sheet L. The recording apparatus of the present embodiment also matches the conveyance direction of the recording apparatus and the generatrix direction (x direction) of the lens apparatus L with respect to the lens sheet L as shown in FIG. Images can be recorded with high accuracy.

  Also in the case as shown in FIG. 1B, the crest of the cylindrical lens 13 may be located on the side of the lens sheet L, or the trough may be located. According to the recording apparatus of the present embodiment, each cylindrical lens 13 of the lenticular lens 7 is positioned at a predetermined position regardless of whether the crest or trough of the cylindrical lens 13 is located on the side of the lens sheet L. become.

=== This Embodiment ===
<Outline of recording device>
FIG. 2 is a block diagram for explaining a schematic configuration of the recording apparatus. FIG. 3 is a perspective view of the recording apparatus as viewed from the rear. In FIG. 3, the transport direction of the recording apparatus 100 is the X direction, the main scanning direction of the head is the Y direction, and the vertical direction is the Z direction (X, Y, and Z are capital letters). As will be described later, the X direction (the conveyance direction of the recording apparatus 100) and the x direction (the generatrix direction of the lens of the lens sheet L) coincide with each other.

  The computer 110 which is an external device generates an image to be recorded on the recording device 100 and transmits recording data to the recording device 100. When recording on the lens sheet L, the computer 110 generates a recording image by processing and synthesizing a plurality of images designated by the user according to the lens pitch or the like, and records the images. The recording data is transmitted to the recording apparatus 100. Note that the recording apparatus 100 may have a function of generating recording data.

  The recording apparatus 100 performs recording on a medium based on the recording data received from the computer 110. When recording on the lens sheet L, an image is recorded on the back surface of the lens sheet L based on recording data generated according to the lens pitch.

  The recording apparatus 100 includes a housing 2, a supply cassette 200 including a guide 3, a transport roller 4 and a paper discharge roller 5, a head 6, and the like. The housing 2 is an exterior body of the recording apparatus 100. The supply cassette 200 is a cassette set in the recording apparatus 100 in order to supply the lens sheet L into the recording apparatus 100. The transport roller 4 and the paper discharge roller 5 transport the lens sheet L supplied from the supply cassette 200 in the transport direction. The head 6 performs recording on the lens sheet L.

  The housing 2 is provided with a supply cassette insertion portion 9 and a paper discharge opening 10. The lens sheet L supplied from the supply cassette insertion unit 9 is conveyed in the conveyance direction by the conveyance roller 4 and the paper discharge roller 5, and is recorded by the head 6, and is output from the paper discharge opening 10 to the outside of the recording apparatus 100. To be discharged.

  The supply cassette 200 has a rectangular outer frame, and has a guide 3 therein. In addition, a slit 210, which will be described later, is formed in the upper portion of the supply cassette 200, and the lens sheet L in the supply cassette 200 can be pressed through the slit 210. The supply cassette 200 will be described in detail after FIG.

  The guide 3 is disposed at the bottom of the supply cassette 200 and has a rectangular plate-like body as a whole. The guide 3 is formed from the lens sheet insertion port 202 of the supply cassette 200 to the lens sheet supply port 204 in the conveyance direction. Further, with respect to the Y direction (or the width direction of the lens sheet L), there is a width that can support the entire width of the lens sheet L.

  A transport roller 4 and a paper discharge roller 5 are disposed before and after the head 6. The transport roller 4 is rotationally driven by a transport motor 16, and the paper discharge roller 5 is rotationally driven by a paper discharge motor 17.

  The head 6 is an ink jet recording head that ejects ink, and is attached to the lower surface of the carriage 18. The carriage 18 is supported by a carriage guide 19 provided along the Y direction so as to be movable in the Y direction, and is attached to a timing belt 21 driven by a carriage motor 20. Therefore, when the timing belt 21 is rotationally driven by the carriage motor 20, the head 6 can reciprocate in the Y direction together with the carriage 18.

  The controller controls the conveyance of the lens sheet L in the conveyance direction by controlling the conveyance motor 16 and the paper discharge roller 17. The controller controls the movement of the head 6 by controlling the carriage motor 20. The controller controls ink ejection from the head 6. As a result, the controller can record an image at a desired position on the lens sheet L.

  When recording an image on the lens sheet L, the lens sheet L is placed on the guide 3 so that the image forming layer 8 side faces the head 6 and the lenticular lens 7 side contacts the guide 3. Then, the lens sheet L is moved in the conveying direction while being pressed against the guide 3 through the slit 210. Thereafter, the lens sheet L is transported in the transport direction by the transport roller 4 and moved to the lower portion of the head 6. As a result, the head 6 performs recording on the image forming layer 8, and a recorded material is created in which the image recorded on the image forming layer 8 can be viewed from the lenticular lens 7 side.

<Guide structure>
4 is an enlarged view of a portion R shown in FIG.
The guide 3 includes a bottom surface 11 of the supply cassette and an engaging portion 12. The engaging portion 12 has the same shape as the lenticular lens 7 and is provided on the bottom surface 11. That is, the linear protrusions 14 having the same shape as the cylindrical lens 13 are arranged at the same pitch as the lens pitch. For this reason, the engaging part 12 may be formed by diverting the lenticular lens 7. Since the shape of the engaging portion 12 is the same as that of the lenticular lens 7, the most protruding portion of the convex portion 14 of the engaging portion 12 is referred to as “mountain”, and the concave portion between the convex portions 14 is defined here. Sometimes called a “valley”, a line of mountains is called a “ridge line”, and a direction parallel to the ridge line is sometimes called a “bus line direction”.

  The position of the guide 3 is adjusted so that the generatrix direction of the projection 14 of the filaments coincides with the conveyance direction (X direction) of the recording apparatus 100 and is attached to the recording apparatus 100. Moreover, the convex part 14 of a filament is arranged in parallel over the width | variety wider than the width | variety of the lens sheet L. FIG.

  Since the engaging portion 12 has the same shape as the lenticular lens 7, the cylindrical lens 13 of the lenticular lens 7 and the convex portion of the guide 3 when the lens sheet L is placed on the guide 3 with the lenticular lens 7 side down. 14, the convex portion 14 of the guide 3 is positioned between the peaks of the cylindrical lens 13, and the peak of the cylindrical lens 13 is positioned between the convex portions 14 and 14 of the guide 3. As a result, the movement of the lens sheet L in the Y direction with respect to the guide 3 is limited, and the lens sheet L is positioned in the Y direction. On the other hand, the lens sheet L can be conveyed along the conveyance direction which is the generatrix direction of the convex portion 14 of the guide 3 because there is no restriction in the generatrix direction of the convex portion 14 (the vertical direction in FIG. 4, the X direction). is there. That is, the guide 3 guides the lens sheet L in the transport direction while restricting movement in the Y direction.

<Preventing skew by pressing force>
The lens sheet L may be placed obliquely with respect to the guide 3. That is, the lens sheet L may be placed on the guide 3 in a state where the conveyance direction (X direction) of the recording apparatus 100 and the generatrix direction (x direction) of the lens of the lens sheet L do not match. In such a state, the lens sheet L is not positioned in the Y direction. However, even in such a case, the lens sheet L can be prevented from being skewed and conveyed by conveying the lens sheet L while pressing it against the guide 3.

  Prepare two lens sheets. At first, in the state where the generatrix directions of the two lens sheets are crossed (the crests of the lenses are not meshed), the lens surfaces face each other and overlap each other. When the two lens sheets are slid (rubbed together), the generatrix directions of the two lens sheets coincide with each other, and the crests of the lenses engage with each other. The fact that the recording apparatus 100 of the present embodiment can prevent skewing by conveying the lens sheet L while pressing it against the guide 3 is based on this phenomenon.

  FIG. 5A is a top view of the lens sheet placed obliquely with respect to the guide 3. 5B is a cross-sectional view taken along line AA in FIG. 5A. 5C is a cross-sectional view taken along line BB in FIG. 5A. In FIG. 5A, the positions of the guide 3 and the peak of the lens are indicated by dotted lines, the positions of the valleys are indicated by solid lines, the guide 3 is indicated by thick lines, and the lenses are indicated by thin lines. In order to simplify the description, the number of peaks and valleys is reduced.

  When the lens sheet L is placed obliquely with respect to the guide 3 as shown in FIG. 5A, there is a place where the peaks of the lens sheet L and the guide 3 contact each other as shown in FIG. 5B. Therefore, the distance between the lens sheet L and the guide 3 is wider than the state of FIG. For this reason, as shown to FIG. 5C, the part from which the peak of the lens sheet L leaves | separates from the guide 3 arises. When the pressing force acts on the position of the BB cross section in the state of FIG. 5C, the lens sheet L bends so that the crest of the lens sheet L enters and contacts the trough of the guide 3 as shown in FIG. As a result, when a pressing force acts on the position of the BB cross section, the movement of the lens sheet L in the left-right direction (Y direction) is restricted at the position of the BB cross section.

  When the lens sheet L is transported in the transport direction from that state, the position where the pressing force acts deviates from the position of the BB cross section. As a result, the crest of the lens sheet L enters the trough of the guide 3 as shown in FIG. At this time, the state as shown in FIG. 4 is maintained at the position of the BB cross section, and the state as shown in FIG. 4 is attempted even at a position shifted from the BB cross section. At a position where the peak of the lens sheet L is in contact with the peak of the guide 3 (see FIGS. 5A and 5B), the peak of the lens sheet L slides along the curved surface of the guide 3 (in this case, the peak of the lens sheet L is Slide to the right). As a result, the lens sheet L rotates in the direction in which the skew is eliminated (counterclockwise in FIG. 5A), and the skew is corrected (the bus line direction of the lens sheet L and the bus bar direction of the guide 3 coincide).

  Once the skew is corrected and the crests of the lens sheet L and the crests of the guide 3 are engaged with each other, the movement of the lens sheet L is no longer restricted, and no force acting on the lens sheet L in the rotation direction is generated. . Further, when the lens sheet L receives a pressing force in a state where the crests of the lens sheet L and the crests of the guide 3 are engaged with each other, there is no gap between the lens sheet L and the guide 3, and the lens sheet L with respect to the guide 3 is lost. Since the movement of is limited only in the X direction, skewing is continuously prevented.

  In this embodiment, the lens sheet L is conveyed in the conveyance direction while being pressed against the guide 3 from the slit 210 of the supply cassette 200. Accordingly, the skew of the lens sheet L is prevented, and the X direction (the conveyance direction of the recording apparatus 100) and the x direction (the generatrix direction of the lens of the lens sheet L) coincide. Then, the lens sheet L is supplied to the conveying roller 4 while the skew of the lens sheet L is prevented.

=== Guide Modification ===
<About arrangement>
FIG. 6 is a diagram illustrating a relationship between the supply cassette 200 and the recording apparatus 100 in the modified example. In FIG. 3, the guide 3 does not exist after being discharged from the supply cassette 200, but in FIG. 6, the lens sheet L is conveyed while being positioned by the guide 3 even after being discharged from the supply cassette 200. By doing so, the skew of the lens sheet L is further prevented, and the X direction (the conveyance direction of the recording apparatus 100) and the x direction (the generatrix direction of the lens of the lens sheet L) coincide.

<About the shape of the engaging part (1)>
FIG. 7A is an explanatory diagram of a cross-sectional shape of the engaging portion of the guide of FIG. The aforementioned guide 3 had the same shape as the lenticular lens 7.
However, the engaging portion 12 of the guide 3 is not limited to such a shape. Hereinafter, modified examples of the shape of the engaging portion 12 of the guide 3 will be described. Note that any of the following engaging portions 12 has a convex portion 14 along the transport direction, as in FIG. 7A.

  FIG. 7B is an explanatory diagram of a cross-sectional shape of the engaging portion according to the first modification. The cross-sectional shape of the engaging portion 12 of the first modification is the opposite shape of the lenticular lens 7. In other words, the convex portion 14 of the engaging portion 12 of the first modification has a shape that fits the concave portion of the lenticular lens 7. For this reason, in FIG. 7A, the center of curvature of the convex portion 14 was on the inner side (lower side) of the engaging portion 12, but the center of curvature of the convex portion 14 of the engaging portion 12 of the first modified example is the engaging portion 12. Outside (upper). With such an engaging portion 12 of the first modified example, the restraint in the Y direction of the lens sheet L can be strengthened.

  FIG. 7C is an explanatory diagram of a cross-sectional shape of the engaging portion of the second modified example. The engaging part 12 of the second modified example does not have a curved surface, and the cross section of the convex part 14 is triangular. Even with such a shape, the lens sheet L can be restrained in the Y direction.

  FIG. 7D is an explanatory diagram of a cross-sectional shape of an engaging portion according to a fourth modified example. Compared with FIGS. 7A to 7C, the engagement portion 12 of the fourth modification example has a double spacing between the convex portions 14. Thus, even if the interval between the convex portions 14 is an integral multiple of the lens pitch p, the convex portion 14 of the guide 3 is located in the valley of the cylindrical lens 13 when the lens sheet L is placed on the guide 3. The movement of the sheet L in the Y direction with respect to the guide 3 is limited, and the sheet L is positioned in the Y direction.

  FIG. 7E is an explanatory diagram of a cross-sectional shape of an engaging portion according to a fourth modification. As for the engaging part 12 of a 3rd modification, the cross section of the convex part 14 is a rectangular shape. Even with such a shape, the lens sheet L can be restrained in the Y direction. However, since the engagement portion 12 in FIGS. 7A to 7D is less likely to form a gap with the lens than the engagement portion 12 in FIG. 7E, the positioning accuracy is higher.

<About the shape of the engaging part (2)>
FIG. 8A is an explanatory diagram of an end face on the upstream side in the conveyance direction of the guide of FIG. 3. As shown in the figure, when the normal direction of the end surface 3A of the guide 3 is the conveyance direction (X direction), when the lens sheet L is inserted from the lens sheet insertion port 202 of the supply cassette 200, the upper end of the lens sheet L is the guide 3. It is difficult to insert the lens sheet L by hitting the end surface 3A.

  FIG. 8B is an explanatory diagram of a modification of the end face shape of the guide. In the modification, the end surface of the guide 3 is inclined so that the normal direction of the end surface 3B on the upstream side in the conveyance direction of the guide 3 has a Z-direction component. Thus, when the upper end of the lens sheet L hits the end surface 3B of the guide 3, the upper end of the lens sheet L is guided upward, and the lens sheet L can be easily inserted into the lens sheet insertion port 202.

<About the shape of the engaging part (3)>
FIG. 9A is an explanatory diagram of the end shape of the engaging portion of the guide of FIG. As shown in the figure, when the cross-sectional shape of the engaging portion 12 is the same up to the end portion, when the lens sheet L is inserted from the lens sheet insertion port 202, the upper end of the lens sheet L becomes the convex portion 14 of the engaging portion 12. It is hard to insert the lens sheet L.

  9B to 9E are modifications of the end shape of the convex portion of the engaging portion. In this way, the convex portion 14 of the engaging portion 12 may be made smaller toward the upstream side in the transport direction. Thereby, the end of the convex portion 14 of the engagement portion 12 can easily enter between the peaks of the lens sheet L to be inserted, guide the peaks of the lens sheet L to the valleys of the engagement portion 12, and the lens sheet. It becomes easy to guide the valley of L to the mountain of the engaging portion 12.

<About the shape of the engaging part (4)>
The above-mentioned convex part 14 was the shape of the filament along the X direction (conveyance direction). However, the shape of the convex part 14 is not restricted to a filament.

  FIG. 10 is a view of a part of the guide according to the modification viewed from above. A large number of hemispherical protrusions are provided on the engaging portion 12 in a square lattice shape. The distance between the protrusions 34 is the same as the lens pitch p of the lenticular lens 7. In other words, in this modified example, by providing a plurality of protrusions 34 along the transport direction, convex portions 14 along the transport direction are formed, and such convex portions 14 are at the same interval as the lens pitch p. Are lined up. Even with such a guide 3, the lens sheet L can be conveyed in the X direction while constraining the lens sheet L in the Y direction.

  In addition, although the shape of the protrusion 34 of this modification was hemispherical, it may be a conical shape or a quadrangular pyramid shape (pyramid shape). Further, the interval between the protrusions in the Y direction is not necessarily the same as the lens pitch p of the lenticular lens 7, and may be an interval that is an integral multiple of the lens pitch. Further, the protrusions 34 may not be arranged in the Y direction.

<About the number of convex parts>
The guide 3 described above was provided with a large number of convex portions 14 continuously in the Y direction at the same pitch as the lens pitch of the lenticular lens 7. However, the guide 3 may not have such a shape.

FIG. 11A is an explanatory diagram of a first modification of the number of convex portions. As described above, even if the convex portion 14 is singular, the guide 3 restrains the lens sheet L in the Y direction if the convex portion 14 is formed along the conveyance direction (the direction perpendicular to the paper surface in the drawing). However, it can be conveyed in the conveying direction.
FIG. 11B is an explanatory diagram of a second modification of the number of convex portions. Thus, the plurality of convex portions 14 may be arranged at the same interval as the lens pitch p of the lenticular lens 7.
FIG. 11C is an explanatory diagram of a third modification of the number of convex portions. As described above, the plurality of convex portions 14 may be arranged at intervals of an integral multiple of the lens pitch p of the lenticular lens 7.
FIG. 11D is an explanatory diagram of a fourth modification of the number of convex portions. When a plurality of convex portions 14 are provided on the guide 3, it is not always necessary to have an equal interval, and the interval between the convex portions 14 may be the lens pitch p of the lenticular lens 7 or an integer multiple thereof.

  11A to 11D, the shape of the convex portion 14 is a cylindrical shape, but may be another shape as described above. Here, the description is omitted.

=== Adjustment of supply cassette position ===
The supply cassette 200 needs to be attached to the recording apparatus 100 so that the guide 3 is adjusted so that the direction of the convex portion 14 is along the transport direction. Here, an adjustment method when the supply cassette 200 including the guide 3 is attached will be described.

FIG. 12 is an explanatory diagram of an inspection image.
The inspection image CM is an image having a plurality of lines Ln. The center line LA of the plurality of lines Ln is a line along the conveyance direction on the image data. The lines Ln on the left and right of the line LA of the inspection image CM are lines in which the slopes are accumulated in order by a certain angle. For example, the line Ln on the right side of the line LA is set so that the inclination angle is increased in order in 0.01 degree clockwise in the conveyance direction on the image data. Further, the line Ln on the left side of the line LA is set so that the inclination angle is sequentially increased in increments of 0.01 degrees counterclockwise in the conveyance direction on the image data.

  After the supply cassette 200 including the guide 3 is attached to the recording apparatus 100, the recording apparatus 100 uses the inspection image CM as a lens to inspect whether the generatrix direction of the convex portion 14 of the guide 3 is along the transport direction. Record on sheet L. If the recording apparatus 100 is ideally assembled, the line LA is recorded on the lens sheet L in accordance with the conveyance direction. That is, if the recording apparatus 100 is ideally assembled, the line LA should be recorded along the generatrix direction of the lens sheet L. After the recording apparatus 100 records the inspection image on the lens sheet L, the inspector inspects the inspection image from the lenticular lens 7 side.

  FIG. 13 is an explanatory diagram of an inspection image viewed from the lenticular lens side. Of the plurality of lines Ln, the line Ln recorded so as to coincide with the generatrix direction of the lenticular lens 7 can be visually recognized as one continuous line. On the other hand, the line Ln that is not recorded along the generatrix direction of the lenticular lens 7 is recorded across the plurality of cylindrical lenses 13, and thus becomes a discontinuously divided line such as a line LC. If the recording apparatus 100 is ideally assembled, the line LA should be visually recognized as one line. On the other hand, if the generatrix direction of the convex portion 14 of the guide 3 is inclined with respect to the transport direction, the line LA is visually recognized as a divided line, and another line LB corresponding to the inclination angle is regarded as one line. Visible.

  Therefore, the inspector specifies a line that can be visually recognized, and adjusts the mounting angle of the supply cassette 200 including the guide 3 by an angle corresponding to the line. For example, in this case, the mounting angle of the guide 3 is adjusted so as to be inclined by 0.03 degrees with respect to the current mounting angle of the guide 3. Thus, the supply cassette 200 including the guide 3 is attached to the recording apparatus 100 so that the convex portion 14 of the guide 3 is along the transport direction.

  In the above description, the inspector visually recognizes the inspection image recorded on the lens sheet L, but the present invention is not limited to this. For example, the scanner may read an inspection image recorded on the lens sheet L, and the attachment angle of the supply cassette 200 including the guide 3 may be determined based on the read result.

<Paper feeding cassette in this embodiment>
FIG. 14 is a diagram illustrating the supply cassette 200 in the present embodiment. The supply cassette 200 is provided with a lens sheet insertion port 202 and a lens sheet supply port 204. The lens sheet insertion port 202 is an insertion port for inserting a lens sheet into the supply cassette. The lens sheet supply port 204 is a supply port for supplying the lens sheet guided by the guide into the printer. The interval from the lens sheet insertion port 202 of the supply cassette 200 to the lens sheet supply port 204 is formed to be longer than the length in the generatrix direction of a standard size lens sheet that can be inserted into the lens sheet insertion port. .

  As described above, the guide 3 is formed on the bottom surface 11 of the supply cassette 200. Therefore, when the lens sheet L passes over the guide, the cylindrical lens of the lenticular lens and the convex portion of the guide 3 mesh with each other, and the convex portion of the guide is positioned between the peaks of the cylindrical lens. A mountain is located between the protrusions of the guide. As a result, the movement of the lens sheet L in the Y direction with respect to the guide 3 is limited, and the lens sheet L is positioned in the Y direction.

  Although it is possible to limit the movement in the Y direction with respect to the guide 3 due to the weight of the lens sheet L, the lens sheet is more reliably applied when a force that presses the lens sheet L against the guide 3 is applied. L is restricted from moving in the Y direction with respect to the guide 3.

  In the supply cassette 200 in the present embodiment, the pressing force is applied to the upper portion of the supply cassette 200 so that the supply can be performed while the force that presses the lens sheet L against the guide 3 is applied. The central slit 210 is formed.

  The central slit 210 is formed substantially at the center of the supply cassette 200, and is formed so that the width in the conveyance direction of the lens sheet L is longer than the width in the direction intersecting the conveyance direction. When such a supply cassette 200 is used, after the lens sheet L is inserted into the lens sheet insertion slot 202, for example, the printing surface of the lens sheet L is pressed from the central slit 210 by, for example, a human finger in the conveyance direction. Be transported. In this way, the lens sheet L can be conveyed in the conveying direction while pressing the lens sheet L from the central slit 210 against the guide, so that the lens sheet L can follow the generatrix direction of the convex portion of the guide until the lens sheet L contacts the conveying roller. And the conveyance accuracy can be improved. Further, even after the lens sheet comes into contact with the conveyance roller, it can be conveyed while continuously pressing the printing surface from the central slit, so the lens sheet L is continuously conveyed along the generatrix direction of the convex portion of the guide 3. It is possible to improve the conveyance accuracy during printing.

  FIG. 15 is a diagram illustrating a supply cassette 200 ′ according to the first modification. In the supply cassette 200 ′ of the first modified example, side slits 220 are provided on the side of the upper side of the supply cassette 200 ′ instead of the above-described central slit 210. The side slits 220 are formed so that the width in the transport direction is approximately the same as the width in the transport direction of the central slit 210 described above. In addition, it is assumed that the width of the side slit 220 in a direction intersecting the conveyance direction is sufficiently large so that the lens sheet L can be pressed through the side slit 220.

  When such a supply cassette 200 ′ is used, the lens sheet L is inserted into the lens sheet insertion port 202, and then the upper side of the lens sheet L is pressed from the side slit 220 against the guide 3 with a human finger or the like in the conveyance direction. Can be transported. By doing so, the lens sheet L can be conveyed while improving the conveyance accuracy. However, since it is not necessary to further press the center of the printing surface of the lens sheet L, for example, it can be pressed by a human finger or the like. Even if it exists, it can be made to convey in a conveyance direction, without attaching fats and oils etc. to the printing surface center part.

  FIG. 16 is a diagram for explaining a supply cassette 200 ″ according to a second modification. In the supply cassette 200 ″ of the second modified example, an insertion port side slit 230 formed by cutting from the lens sheet insertion port 202 side on the upper side of the supply cassette 200 ′ instead of the above-described central slit 210 is provided. Is provided. The insertion-port-side slit 230 is formed so that the width in the conveyance direction is approximately the same as the width in the conveyance direction of the central slit 210 described above. In addition, it is assumed that the width of the insertion port side slit 230 in a direction intersecting the conveyance direction is sufficiently large to allow the lens sheet L to be pressed through the insertion port side slit 230.

  When such a supply cassette 220 ′ is used, after the lens sheet L is inserted into the lens sheet insertion port 202, the lens sheet L is conveyed from the insertion port side slit 230 while pressing the upper portion of the lens sheet L against the guide by a human finger, for example. be able to.

  All the above-mentioned types of slits may be provided in the supply cassette. That is, all of the center slit 210, the side surface slit 220, and the insertion port side slit 230 may be provided in the supply cassette.

  FIG. 17 is a diagram illustrating a supply cassette 200 ″ ″ according to the third embodiment. In the supply cassette 200 ″ of the third embodiment, a pressing member 240 for pressing the lens sheet L from above is provided in the above-described central slit 210. The central slit 210 serves as a guide for allowing the pressing member 240 to move smoothly in the transport direction. Further, the pressing member 240 includes a grip part 241 and a lens sheet pressing part 242 that can move in the transport direction integrally with the grip part 241 so as to be easily operated.

  When such a supply cassette 200 ″ ″ is used, the lens sheet L is inserted into the lens insertion opening 202 and then disposed above the guide 3 and below the lens sheet pressing portion 242. Then, the grip portion 241 conveys the lens sheet L in the conveying direction while pressing the upper portion of the lens sheet L against the guide 3. By doing in this way, the crest of the lens sheet L is guided to the trough of the engaging part of the guide 3 from the above-mentioned effect | action, and it can convey, positioning the lens sheet L about a Y direction.

  Further, according to the supply cassette 200 ′ ″, it is not necessary for a human finger or the like to directly contact the lens sheet L, so that it can be transported in the transport direction without attaching oil or the like to the printing surface of the lens sheet L. .

=== Other Embodiments ===
Although a recording apparatus using a head has been described as an embodiment, the above embodiment is for facilitating the understanding of the present invention and is not intended to limit the present invention. The present invention can be changed and improved without departing from the gist thereof, and it is needless to say that the present invention includes equivalents thereof.

2 housing, 3 guides, 3A and 3B end faces, 4 transport rollers,
5 discharge roller, 6 heads, 7 lenticular lens,
8 image forming layer, 8A ink permeable layer, 8B ink absorbing layer,
9 Supply cassette insertion portion, 10 paper discharge opening, 11 bottom surface,
12 engaging part, 13 cylindrical lens, 14 convex part,
16 transport motor, 17 discharge motor, 18 carriage,
19 Carriage guide, 20 Carriage motor,
21 timing belt, 100 recording device, 110 computer,
200 supply cassette, 202 lens sheet insertion slot,
204 lens sheet supply port, 210 central slit,
220 side slit, 230 insertion slot side slit,
240 pressing member, 241 grip portion, 242 lens sheet pressing portion,
CM inspection image, Ln line, L lens sheet, S paper

Claims (9)

A supply cassette for supplying a recording medium having a lenticular lens to a recording apparatus,
A guide unit for supporting the recording medium and guiding the recording medium along a generatrix direction of the lenticular lens;
An outer frame that covers the guide unit while forming an insertion port for inserting the recording medium and a supply port for supplying the recording medium inserted from the insertion port to the recording apparatus, and is opposed to the guide unit An outer frame having a slit formed along the generatrix direction at a position to be
A pressing member for pressing the recording medium against the guide through the slit;
Supply cassette comprising.   The supply cassette according to claim 1, wherein the slit includes a guide for sliding the pressing member in the generatrix direction.   3. The supply cassette according to claim 1, wherein an interval from the insertion port to the supply port is longer than a length of the recording medium having a fixed size that can be inserted into the insertion port in the bus line direction.   The supply slit according to claim 1, wherein the slit is provided in a central portion of the outer frame. The slit is provided on an end of the direction crossing the generatrix direction in the outer frame, the supply cassette according to any one of claims 1-3. The slit is cut is formed by a from the insertion hole of the recording medium in the outer frame, the supply cassette according to any one of claims 1-3.   The supply cassette according to claim 1, wherein the guide part has a convex part formed along the generatrix direction. (A) a guide unit for supporting a recording medium having a lenticular lens and guiding the recording medium along a generatrix direction of the lenticular lens;
An outer frame that covers the guide unit while forming an insertion port for inserting the recording medium and a supply port for supplying the recording medium inserted from the insertion port to the recording apparatus, and is opposed to the guide unit An outer frame having a slit formed along the generatrix direction at a position to be
A pressing member for pressing the recording medium against the guide through the slit;
A supply cassette comprising:
(B) a head that ejects liquid onto the recording medium supplied from the supply port;
A recording apparatus comprising: While supporting a recording medium having a lenticular lens, a guide portion for guiding the recording medium along a generatrix direction of the lenticular lens, an insertion port for inserting the recording medium, and the insertion inserted from the insertion port An outer frame that covers the guide portion while forming a supply port for supplying a recording medium to the recording apparatus, and has an outer frame that has a slit formed along the generatrix direction at a position facing the guide portion; In a supply method using a supply cassette comprising: a pressing member for pressing the recording medium against the guide portion through the slit;
Inserting a recording medium having a lenticular lens into the insertion slot of the supply cassette;
Conveying the lenticular lens from the slit formed in the supply cassette along the generatrix direction to the supply port facing the insertion port while pressing the recording medium with the pressing member against the guide part;
Discharging the recording medium from the supply port along the generatrix direction;
Including a supply method.

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