The present invention relates to an embossed sheet and a method of manufacturing the same, and in particular to an embossed sheet and a method of manufacturing the same, wherein an embossed pattern, which is used as a lens, is formed on one surface of a sheet, and the sheet is rolled up in the course of manufacturing the same.
An embossed sheet made of resin and used in various optical elements involves a Fresnel lens, a lenticular lens, and the like, and is used in various fields. Such an embossed sheet has a surface on which a regular embossed pattern, which is used as a lens, is formed, and this embossed pattern provides optical performance. As a method for manufacturing such an embossed sheet, there are generally an extrusion molding method, an extrusion laminating method, and a 2P method. The extrusion molding method is such that a strip-like resin sheet obtained by extruding thermoplastic molten resin in a sheet-like shape from an extrusion die is nipped between a die roller and a nip roller, the inverted shape of an embossed pattern formed on the die roller is transferred to the resin sheet, and the resin sheet after the transfer is separated from the die roller. Then, the separated strip-like embossed sheet is rolled up by a winder. In addition, the extrusion laminating method is the same as the extrusion molding method, except that a strip-like base material is laminated as a support on a resin sheet extruded from an extrusion die.
The 2P method is such that after UV (ultraviolet) curable resin is applied to a support, the support is wrapped on a die roller and is irradiated with UV light while being wrapped, so that a reversal shape of an embossed pattern formed on the die roller is transferred to the resin sheet, and the resin sheet after the transfer is separated from the die roller. Then, the separated strip-like embossed sheet is rolled up by a winder.
As shown in
Regarding a technique of rolling up a sheet or a film, a patent literature 1, for example, describes a technique of performing knurling to form a lot of spherical protrusions on both widthwise end portions of a film, thereby preventing misalignment of roll layers when the film is rolled up.
In addition, a patent literature 2 introduces a technique improved from the patent literature 1. That is, since the spherical protrusions are not sufficiently formed by knurling an unsoftened film after being manufactured like the patent literature 1, the patent literature 2 suggests knurling, by an emboss roller, a softened film when the film is formed in an extruding manner.
However, though making it possible to prevent misalignment of roll layers, knurling in the patent literatures 1 and 2 cannot make it possible to prevent protrusions of an embossed pattern formed on a sheet surface from being crushed when the embossed sheet is rolled up. That is, the patent literatures 1 and 2 do not present the problem of preventing protrusions of an emboss pattern formed on a sheet surface from being crushed when the embossed sheet is rolled up, and do not take a measure to solve the problem, either. In particular, if the embossed sheet has thickness distribution in a product region where the embossed pattern is formed, thicker portions are subjected to winding pressure, by which only the protrusions at the thicker portions might be deformed into an embossed line.
The present invention has been made in view of these circumstances, and an object thereof is to provide an embossed sheet and a method of manufacturing the same, wherein an embossed pattern is prevented from being crushed when the embossed sheet is rolled up so that the embossed pattern can provide its original function, such as optical performance.
In order to achieve the object, an embossed sheet of the present invention is an embossed sheet obtained by forming an embossed pattern on a surface of a strip-like sheet and rolled up, including band-like bump portions thicker than the other portions of the sheet, the band-like bump portions being formed on widthwise both end portions of the sheet along a longitudinal direction of the sheet.
According to the embossed sheet of the present invention, the band-like bump portions thicker than the other portions of the sheet are formed on widthwise both end portions of the sheet along a longitudinal direction of the sheet. Therefore, when the embossed sheet is rolled up, the band-like bump portions come into contact with the band-like bump portions on the embossed sheet wound thereon. As a result, a clearance due to the band-like bump portions is formed between roll layers of the rolled-up embossed sheet.
Thus, since winding pressure of winding tension when the embossed sheet is rolled up can be borne by the band-like bump portions, the winding pressure is not applied to protrusions of the embossed pattern, or, if any, the winding pressure can be remarkably reduced as compared with the embossed sheet having no band-like bump portions. Therefore, since the embossed pattern formed on the sheet surface is prevented from being crushed when the embossed sheet is rolled up, the embossed pattern can provide its original function, such as optical performance.
In the embossed sheet of the present invention, it is preferred that the embossed sheet has a structure where a strip-like base member is laminated on a resin sheet on which the embossed pattern is formed and the band-like bump portions are formed by folding and bonding both end portions of the resin sheet formed to be wider than the strip-like base member to a rear surface of the strip-like base member.
It should be noted that both end portions of the resin sheet formed to be wider than the strip-like base member are referred to as “extended portions”.
This is a preferred aspect of forming the band-like bump portions, and since the extended portions of the resin sheet formed to be wider than the strip-like base member are folded and bonded to the rear surface of the strip-like base member, the band-like bump portions can be formed easily and reliably. In this case, it is preferred that the band-like bump portions include protrusions on widthwise both end portions of the embossed pattern, and the embossed pattern between the band-like bump portions formed in a widthwise direction of the embossed sheet is produced as a product region.
Thus, since the band-like bump portions include the protrusions on widthwise both end portions of the embossed pattern, a clearance corresponding to the thickness of the extended portion can be reliably formed between roll layers of the rolled-up embossed sheet.
In the embossed sheet of the present invention, it is preferred that the embossed sheet has a structure where a strip-like base member is laminated on a resin sheet on which the embossed pattern is formed and the band-like bump portions are formed by folding both end portions of the resin sheet formed to be wider than the strip-like base member to overlap with protrusions on widthwise both end portions of the embossed pattern formed on the resin sheet, and bonding both end portions of the resin sheet to the protrusions.
This is a preferred aspect of forming the band-like bump portions, and since the extended portions are folded to overlap with the protrusions on widthwise both end portions of the embossed pattern and are bonded thereto, a clearance corresponding to the thickness of the extended portion can be reliably formed between roll layers of the rolled-up embossed sheet.
In the embossed sheet of the present invention, it is preferred that the embossed pattern has optical performance. Crushing protrusions of an embossed pattern having optical performance, such as a lenticular lens, is particularly problematic.
In order to achieve the above object, a method of manufacturing an embossed sheet of the present invention is a method of manufacturing an embossed sheet on a sheet surface of which an embossed pattern is formed, including: a strip-like base member supplying step of supplying a strip-like base member from a feeder to a nip point between a die roller and a nip roller; a resin sheet supplying step of extruding thermoplastic molten resin from an extrusion die into a sheet-like shape, thereby forming a strip-like resin sheet wider than the strip-like base member, and supplying the formed resin sheet to the nip point between the die roller and the strip-like base member; a transferring step of nipping the resin sheet and the strip-like base member supplied to the nip point by the die roller and the nip roller, thereby laminating the resin sheet on the strip-like base member, and transferring an inverted shape of the embossed pattern formed on the die roller to the resin sheet, and thereafter cooling solidifying the resin sheet; a separating step of separating the strip-like base member laminated with the resin sheet from the die roller after the transferring step; a folding step of folding both end portions of the wider resin sheet to a rear surface of the strip-like base member after the separating step; a bonding step of bonding the folded portions to the strip-like base member; and a rolling-up step of rolling up the strip-like base member laminated with the resin sheet after the bonding step.
According to the manufacturing method of the present invention, band-like bump portions can be formed on widthwise both end portions of the sheet along a longitudinal direction of the sheet to be thicker than the other portions of the sheet.
Thus, since the band-like bump portions function as bridge beams even when the embossed sheet is rolled up, the embossed pattern is prevented from being crushed. Therefore, the embossed sheet can provide an original function of the embossed pattern, such as optical performance.
In addition, since the band-like bump portions are formed by folding both end portions of the wider resin sheet to the rear surface of the strip-like base member and bonding the same thereto, the band-like bump portions can be formed easily and reliably.
In the method of manufacturing an embossed sheet of the present invention, it is preferred that the resin sheet and an adhesive resin layer are coextruded from the extrusion die such that the adhesive resin layer is formed on a rear surface of the resin sheet extruded from the extrusion die.
This makes it possible to perform simultaneously the step of folding both end portions of the wider resin sheet to the rear surface of the strip-like base member and the step of bonding the same thereto.
In order to achieve the above object, a method of manufacturing an embossed sheet of the present invention is a method of manufacturing an embossed sheet on a sheet surface of which an embossed pattern is formed, including: a strip-like base member supplying step of supplying a strip-like base member from a feeder to a nip point between a die roller and a nip roller; a resin sheet supplying step of extruding thermoplastic molten resin from an extrusion die into a sheet-like shape, thereby forming a strip-like resin sheet wider than the strip-like base member, and supplying the formed resin sheet to the nip point between the die roller and the strip-like base member; a transferring step of nipping the resin sheet and the strip-like base member supplied to the nip point by the die roller and the nip roller, thereby laminating the resin sheet on the strip-like base member, and transferring an inverted shape of the embossed pattern formed on the die roller to the resin sheet, and thereafter cooling and solidifying the resin sheet; a separating step of separating the strip-like base member laminated with the resin sheet from the die roller after the transferring step; a folding step of folding both end portions of the wide resin sheet to overlap with a portion of the embossed pattern on the resin sheet after the separating step; a bonding step of bonding the folded portions to the overlapped portions of the resin sheet; and a rolling-up step of rolling up the strip-like base member laminated with the resin sheet after the bonding step.
This is another aspect for forming the band-like bump portions easily and reliably, where both end portions of the wide resin sheet are folded to overlap with a portion of the embossed pattern on the resin sheet, and are bonded to the portion of the embossed pattern.
In addition, it is preferred that the rigidity of the strip-like base member to be used is higher than the rigidity of the resin sheet. The rigidity of the embossed sheet manufactured by laminating the resin sheet on the strip-like base member having higher rigidity than the resin sheet can be made higher than the rigidity of an embossed sheet made of only a resin sheet. This makes the embossed sheet between the band-like bump portions less likely to sag when the embossed sheet is rolled up, and therefore the function of the band-like bump portions as bridge beams can be further enhanced. If the rigidity of the embossed sheet is low and therefore the embossed sheet between the band-like bump portions sags, the embossed pattern distant from the band-like bump portions becomes more likely to be crushed while the embossed pattern near the band-like bump portions are prevented from being crushed.
According to the embossed sheet and the method of manufacturing the same of the present invention, the embossed pattern is prevented from being crushed when the embossed sheet is rolled up, and therefore the embossed pattern can provide its original function, such as optical performance.
A part (A) of
Hereinafter, preferred embodiments of an embossed sheet and a method of manufacturing the same of the present invention will be described with reference to the accompanying drawings.
As shown in
Next, the molten resin melted by the extruder 14 is fed to an extrusion die 18 through a feed pipe 16. The extrusion die 18 is mainly composed of a manifold 18A through which the molten resin fed from the extruder 14 flows so as to spread in a widthwise direction of the die, and a slit 18B that is a narrow channel through which the molten resin flowing in a spread manner is extruded outward in a sheet shape.
In this case, it is preferred that a feed block 19, which can merge a plurality of molten resins into a multilayered molten resin, is provided between the feed pipe 16 and the extrusion die 18 so that a resin sheet 20 and an adhesive resin layer 21 (see
Then, a strip-like base member 24 is fed from a feeder 22 to be supplied to a nip point P between a die roller 26 and a nip roller 28, the respective rollers rotating in directions indicated by arrows, while the resin sheet 20 which is wider than the strip-like base member 24 is extruded from the extrusion die 18 to be supplied to the nip point P. In this case, as shown in
In addition, as shown by parts (A) and (B) of
Thus, when the resin sheet 20 and the strip-like base member 24 are nipped by the die roller 26 and the nip roller 28, the resin sheet 20 is laminated on the strip-like base member 24, and the inverted shape 32 of the die roller 26 is transferred to the resin sheet 20 so that the embossed pattern 30 is formed on the resin sheet 20.
Then, during conveyance of the strip-like base member 24 from the nip position P to the position of a separation roller 38 (see
Next, as shown in
The separated strip-like base member 24 passes through a folding device 35. This folding device 35 is a device to fold the extended portions 20A of the wide resin sheet 20 to a rear surface of the strip-like base member 24 and bond them to the strip-like base member 24. Though any folding device is applicable as long as the folding device can perform such folding, for example, as shown in
A guide plate, which can fold the extended portions 20A of the resin sheet 20 to the rear surface of the strip-like base member 24 according to advance of the strip-like base member 24, is formed in the folding tube 35B. Thus, as shown by a part (B) of
Thus, as shown in
Finally, as shown in
Next, a function effect when the embossed sheet 40 thus manufactured is rolled on the winder 42 will be described.
The part (A) of
On both the end portions of the embossed sheet 40 thus manufactured, the band-like bump portions 34 are formed along the longitudinal direction of the resin sheet 20.
Therefore, as shown by the part (B) of
Thus, since winding pressure of winding tension when the embossed sheet 40 is rolled up can be borne by the band-like bump portions 34, the winding pressure is not applied to the protrusions 30A of the embossed pattern 30, or, if any, the applied winding pressure can be reduced as compared with an embossed sheet without the band-like bump portions 34. Therefore, since the embossed pattern 30 formed on the sheet surface is prevented from being crushed even when the embossed sheet 40 is rolled up, an original function of the embossed pattern, such as optical performance, can be exerted.
In this case, as shown by the part (B) of
Thus, as shown by a part (B) of
In addition, since in the band-like bump portions 34 formed in the part (B) of
In both the cases in
Furthermore, a secondary effect from forming the band-like bump portions 34 on both the end portions of the embossed sheet 40 along the longitudinal direction is that the strip-like embossed sheet 40 can be precisely punched into a predetermined size at a punching process. That is, the strip-like embossed sheet 40 is not directly used as an optical element, but unrolled from the winder 42 and conveyed to a punching process (not shown). In this punching process, the embossed sheet 40 is punched into a predetermined size (for example, 12.7 cm×17.8 cm). In this punching, the embossed sheet 40 is required to be punched parallel to a ridge line of a lenticular lens. In order to punch the embossed sheet 40 parallel with a ridge line of a lenticular lens, an edge position controller (EPC) is used to control travelling of the embossed sheet 40 such that a punching blade becomes parallel with the ridge of the lenticular lens in reference to an end portion of the embossed sheet 40. In this case, the position of the end portion of the embossed sheet 40 is stabilized by providing the band-like bump portions 34, and therefore travelling control performed by the EPC can be stabilized.
As described above, according to the present invention, since the embossed pattern 30 is prevented from being crushed even when the embossed sheet is rolled up, the embossed pattern can exert its original function, such as optical performance. In addition, as a secondary effect of the band-like bump portions 34, the band-like bump portions 34 can be utilized as a reference line for travelling control of the embossed sheet 40 for precise blanking.
It should be noted that though
Hereinafter, the strip-like base member 24, the resin sheet 20, the adhesive resin layer 21, and the extrusion die 18 and the respective rollers 26, 28, 38 of the manufacturing apparatus 10 in the present embodiment will be described.
<Strip-Like Base Member>
It is preferred that the strip-like base member 24 has as smooth surface as possible, and has higher rigidity than the resin sheet 20 laminated thereon. In addition, in a case that the embossed sheet 40 to be manufactured is used as an optical element, it is preferred that a transparent strip-like base member 24 is used. Furthermore, the strip-like base member 24 is required to be resistant to the heat of the melt extruded resin sheet 20, and therefore relatively highly heat-resistant polycarbonate resin, polysulfone resin, biaxially-oriented polyethylene terephthalate, or the like can be used. In particular, the biaxially-oriented polyethylene terephthalate is preferred because of its excellent smoothness. Preferably, the strip-like base member 24 has a thickness of 100 μm to 300 μm, more preferably, a thickness of 160 μm to 210 μm.
<Resin Sheet>
Resins that form the resin sheet 20 include, for example, polymethylmethacrylate resin (PMMA), polycarbonate resin, polystyrene resin, methacrylate-styrene copolymer resin (MS resin), acrylonitril styrene copolymer resin (AS resin), polypropylene resin, polyethylene resin, polyethylene terephthalate resin, glycol-modified polyethylene terephthalate resin, polyvinyl chloride resin (PVC), thermoplastic elastomer, or a copolymer thereof, cycloolefin polymer, or the like. In view of ease of melt extrusion, it is preferred that a resin having low melt viscosity is used, such as polymethylmethacrylate resin (PMMA), polycarbonate resin, polystyrene resin, methacrylate-styrene copolymer resin (MS resin), polyethylene resin, polyethylene terephthalate resin, or glycol-modified polyethylene terephthalate resin, and in view of transferability, crack toughness of the sheet, durability of the embossed pattern 30, or the like, it is more preferred that glycol-modified polyethylene terephthalate resin (PETG or the like) is used.
<Adhesive Resin Layer>
The adhesive resin layer 21 is provided with a function for bonding the strip-like base member 24 and the resin sheet 20 together. It is preferred that the adhesive resin layer 21 is further provided with a cushion function. Here, the cushion function means a function of absorbing winding pressure due to winding tension that is applied to the protrusions 30A of the embossed pattern 30 when the embossed sheet 40 is rolled up. Such an adhesive resin layer 21 provided with both adhesiveness and a cushioning property can be modified polyolefin resin, polyester thermoplastic elastomer, or the like. Preferably, the adhesive resin layer 21 has a thickness of 10 μm to 66 μm, more preferably, a thickness of 5 μm to 10 μm.
<Extrusion Die>
It is preferred that the extrusion die 18 has a function of being capable of adjusting the extrusion temperature of the resin sheet 20. That is, the extrusion temperature of the resin sheet 20 extruded from the extrusion die 18 is adjusted and set so that the temperature of the resin sheet 20 at the nip portion P becomes equal to or more than a glass-transition temperature. This is to prevent the nipped resin sheet 20 from being cooled and solidified before the transfer from the die roller 26 is completed. In addition, occurrence of pyrolysis of resin causes such a problem that sheet deterioration occurs in the manufactured embossed sheet 40, and therefore it is preferred that the extrusion temperature of the resin sheet 20 extruded from the extrusion die 18 is set to be as low as possible to the extent that transferring can be performed. In a case where glycol-modified polyethylene terephthalate resin is adopted as a resin material, the discharge temperature of resin from the extrusion die 18 can be in a range of 240 to 300° C., preferably, in a range of 250 to 290° C.
<Each Roller>
As the material for the die roller 26, various iron and steel members, stainless steel, copper, zinc, brass, these metal materials used as core metals and plated with hard chrome (HCr), Cu, Ni, or the like, ceramics, and various composite materials can be adopted.
In addition, as the nip roller 28, various iron and steel members, stainless steel, copper, zinc, brass, or these metal materials used as core metals and having surfaces lined with rubber can be suitably adopted. The nip roller can be provided with a pressure means. In addition, such a configuration that a backup roller further provided on the back side (the opposite side from the die roller) of the nip roller makes it difficult to generate a sag due to reaction force of nip pressure can be adopted.
The separation roller 38 is a roller provided on the opposite side of the die roller 26 from the nip roller 28 so as to face the die roller 26 to separate the surface of the resin sheet 20 from the die roller 26 such that the strip-like base member 24 is wrapped on the separation roller 38. As a material for the separation roller 38, various iron and steel members, stainless steel, copper, zinc, brass, or these metal materials used as core metals and having surfaces lined with rubber can be suitably adopted.
The temperature of the die roller 26 is set such that the temperature of the resin sheet 20 at the nip portion P becomes equal to or more than the glass-transition temperature. This is to prevent the resin sheet 20 from being cooled and solidified before transferring the embossed pattern from the pattern sheet 26 to the resin sheet 20 is completed. On the other hand, in a case where the strip-like base member 24 is separated from the die roller 26 by the separation roller 38, if the bond between the die roller 26 and the resin sheet 20 is too strong, the strip-like base member 24 is unevenly separated and easily deformed into a protrusion shape. Therefore, it is preferred that the temperature of the die roller 26 is set to be as low as possible to the extent that transferring can be performed.
For example, in a case where glycol-modified polyethylene terephthalate resin is adopted as a resin material, the surface temperature of the die roller 26 can be set in a range of 30 to 90° C., preferably, in a range of 40 to 70° C. It should be noted that in order to control the temperature of the die roller 26, a known means, such as filling the inside of the die roller 26 with a heat medium (hot water, oil) and circulating the heat medium, can be adopted.
Next, a specific example of a method of manufacturing the embossed sheet of the present invention will be described.
A die roller 26 which has a diameter of 500 mm and a face length of 1000 mm and which has the embossed pattern shown by the part (A) of
PETG was used as a resin raw material extruded from an extrusion die 18, and a biaxially-oriented PET (polyethylene terephthalate) film having a thickness of 180 μm and a width of 700 mm was used as a strip-like base member 24.
Then, by using the extrusion die 18 having a width of 1000 mm, a resin sheet 20 having an extruded laminate width of 750 mm was formed by extruding the raw resin from the extrusion die 18, and the resin sheet 20 was nipped by the die roller 26 and a nip roller 28. The extrusion temperature of the extrusion die 18 was set at 280° C., and the temperature of the die roller was set at 40° C. Thus, as shown by the part (A) of
Next, the formed laminate film was separated from the die roller 26 by the separation roller 38, and thereafter, by using the folding device 35 in
The extruded laminate width was set to 700 mm, but the extended portions 20A were not formed and therefore a folding process was not performed. The other conditions were the same as in the example.
[Test Result]
As a result, when the embossed sheet 40 of the example manufactured with the extended portions 20A was rolled up by the winder 42, the lenticular lens which was the embossed pattern 30 was not crushed, and kept the same height of the protrusion 30A as designed.
On the other hand, when the embossed sheet 40 of the comparative example manufactured without the extended portions 20A and without performing a folding process was rolled up by the winder 42, the lens lost its shape such that half-round top portions were flatly crushed at a plurality of lengthwise locations of the lenticular lens (see the part (B) of
Number | Date | Country | Kind |
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2011-068591 | Mar 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/054218 | 2/22/2012 | WO | 00 | 9/12/2012 |