JP4419132B2 - Laminating equipment - Google Patents

Description

  The present invention relates to a laminating apparatus for forming a laminating layer on a recording surface of a recording medium on which an image is recorded.

  As a result of various improvements made to the recording apparatus (printer) and the recording medium, the recording system such as the ink jet recording system and the thermal transfer recording system can obtain an image quality comparable to a silver salt color photograph. In recent years, image information captured by a digital camera, digital video, scanner, or the like or electronic image information in a computer has been widely used as a technique for hard copying.

  In addition, in these recording methods, the recording surface of the recording medium is protected to give permanent durability, and the glossiness and smoothness of the recording surface are increased to further improve the image quality. For this purpose, a technique of laminating a laminate layer on a recording surface of a recording medium after image recording is also widely known.

  As an apparatus used for laminating on a recording surface, a recording medium and a laminating material which are laminated by supplying a laminating material comprising a base material and a laminating layer formed so as to be peelable on the base material onto the recording surface. There is a laminating apparatus that transfers a laminate layer onto a recording surface of a recording medium by heat-pressing the substrate with a substantially true cylindrical roller pair, and then peels the substrate from the laminate layer (Patent Document 1).

  However, in the laminating apparatus disclosed in Patent Document 1, every time the recording medium is replaced with one having a different width size, the laminating material must be replaced with one having a suitable width size. However, in this case, an extra portion of the laminate layer (after the lamination process ( It is necessary to cut off a portion that is not laminated on the recording surface (non-laminated portion) along the edge of the recording medium, and in any case, it is complicated.

  For this reason, there is a laminating apparatus that can save the labor of cutting a non-laminate portion (Patent Document 2). FIG. 18 shows a schematic configuration of the laminating apparatus, in which a piece-like recording medium A cut to a predetermined feed length and a laminating material B supplied as a continuous sheet from a roll are passed through a film guide roll F. When the laminated platen roll G passes between the laminated platen roll G and the heated intermediate roll H, the substrate C is peeled off by the peeling roll I arranged on the downstream side. Is substantially the same as the laminating apparatus disclosed in Patent Document 1 in that it is peeled from the laminate layer D. However, in the laminating apparatus disclosed in Patent Document 2, the base material C is peeled off. The non-laminate portion Db is separated from the laminate portion Da and is taken away together with the base material C.

That is, the laminating apparatus disclosed in Patent Document 2 includes a recording medium A and a laminating material that are overlapped by a substantially true cylindrical platen roll G and an intermediate roller H that are both axially supported and relatively energized. B is heated and pressure-bonded and sent to the downstream side while forming a laminate, and then the substrate C is moved in a direction different from the transport direction of the laminate by interposing the peeling roll I. Is peeled off from the laminated portion Da and taken away together with the base material C.
JP-A-58-224779 JP 10-211161 A

  By the way, in any of the above-mentioned Patent Documents 1 and 2, the laminate material B is configured to be thermocompression bonded to the recording medium A with a substantially true cylindrical roll (in Patent Document 2, a platen roll G and an intermediate roll H). Therefore, there is a problem that the laminate material B cannot be uniformly pressed against the recording surface of the recording medium A, and the laminate material B cannot be uniformly pressed against the recording surface. That is, the conventional laminating apparatus is configured to heat and press the laminate material B to the recording surface with a substantially true cylindrical roll (roller) in which both ends are urged. Acts as a concentrated load, and the urging force causes the roller to bend. Therefore, when the laminate material is heated and pressure-bonded to the recording surface of the base material, a substantially central portion in the axial direction of the roller is deflected in a direction away from the laminate material and the recording medium, and the laminate material is There is a problem in that the laminate material B cannot be uniformly pressed against the recording surface.

  Therefore, the present invention can be applied to the recording of the laminate material and the recording medium even when the lamination material is heated and pressed by a pressure roller supported at both ends while being heated and pressed to the recording surface of the recording medium. It is an object of the present invention to provide a laminating apparatus that can uniformly heat-press the surface and improve the quality of the finished product.

The laminating apparatus according to the present invention includes a pressure roller that is supported at both ends and urged in a direction substantially perpendicular to the axis, and the pressure roller is provided on a recording surface of a sheet-like recording medium. In a laminating apparatus configured to heat and pressure-bond the laminated material and the recording surface while heating the laminated material , the laminating material has a laminating material from a plane area of the recording medium. A laminating layer that is transferred to the recording surface in a wide area is employed, and the pressure roller is formed in a drum shape by reducing the outer diameter from the substantially central portion in the axial direction toward both ends, is configured to elastically deformed by the urging, and, between the object transfer means for transferring the laminate and the laminate layer, a recording medium so that the recording surface faces the laminate layer In a state of being interposed, the laminate material is configured to be heat-pressed to the recording medium and the transfer target, and the surface opposite to the recording surface of the recording medium and the transfer target are separated from each other. The recording medium to which the laminate layer is adhered and the transfer means are configured to move relative to each other. Note that “elastically deformed by urging” means that the shaft itself of the pressure roller bends due to urging, or the outer peripheral surface is deformed when the outer peripheral surface of the pressure roller is made of an elastic material such as rubber. And both the shaft body and the outer peripheral surface are deformed.

  According to the laminating apparatus having the above configuration, the pressure roller that heat-presses the laminating material to the recording medium is formed in a drum shape by reducing the outer diameter from the substantially central portion in the axial direction toward both ends. Since it is configured to be elastically deformed by urging, when the laminate material is pressed by urging both ends of the pressure roller, first, the central portion of the pressure roller contacts the laminate material. Then, the pressure roller is elastically deformed by the urging of both ends, and the outer peripheral surface of the pressure roller contacts the laminate material over the entire length, and the laminate material is uniformly pressed against the recording medium. The recording surface is uniformly heat-pressed.

  Therefore, the laminating apparatus can uniformly heat and press the laminate material and the recording surface of the recording medium even when the laminating material is pressed against the recording medium while being heated by the pressure roller. Can be improved.

  As one aspect of the present invention, it comprises a roller that is pivotally supported at both ends so that the axis is substantially parallel to the axis of the pressure roller and receives the biasing force from the pressure roller via the laminate material and the recording medium. The roller is formed in a drum shape with an outer diameter being reduced from the substantially central portion in the axial direction toward both ends, and is configured to be elastically deformed by receiving the urging force. At least one of these may be configured to be rotationally driven. “Being elastically deformed by being biased” means that the roller shaft itself bends by the biasing force of the biasing roller and its reaction force, or that the outer peripheral surface of the roller is an elastic material such as rubber. This includes that the outer peripheral surface is deformed in the case of being configured, and that both the shaft body and the outer peripheral surface are deformed.

  In this case, the roller and the pressure roller are relatively elastically deformed by the urging force and the reaction force against the pressure roller after the rollers and the center portion of the pressure roller are in contact with each other. In a state where the recording medium is pressed, the laminate material and the recording medium are pressed over substantially the entire length of the roller and the pressing roller. Then, by rotation driving of at least one of the roller and the pressure roller, the laminate material is heated and pressure-bonded uniformly to the recording surface to form a laminate, and is conveyed to the downstream side by pressure. If the laminate material is conveyed in this way, the heating position of the laminate material is displaced over time, so that a situation in which a certain portion of the laminate material is excessively heated is prevented. be able to.

In this case, as further comprising the under film supply unit for supplying under film between the rollers and the pressure rollers as wide a the transfer means than the planar area of the recording medium, a laminate layer on the recording surface is opposed, laminate It is preferable that the recording medium is interposed between the recording medium and the under film, and the laminate is heated and pressure-bonded to the recording medium and the under film by the roller and the pressure roller.

  In this way, by laminating the laminate material to the recording medium by thermocompression bonding, the laminate layer of the laminate material adheres to the entire recording surface of the recording medium, and the portion protruding from the recording surface becomes an under film. In close contact.

  In this state, when the under film is separated from the recording surface of the recording medium on the opposite side, the laminate layer is pulled (pulled) to the opposite side of the recording medium. Since the tensile force acts intensively along the boundary between the part with and without the part (that is, the edge of the recording medium), the part where the laminate layer and the recording surface are pressure-bonded (on the recording surface) Of course, the laminate portion where the laminate layer is laminated) and the portion where the laminate layer and the under film are pressure-bonded (non-laminate portion not laminated on the recording medium) are separated on the recording surface of the recording medium. The edge of the formed laminate layer is clean along the edge of the recording medium. Therefore, when the laminating process is performed by the laminating apparatus, the recording surface of the recording medium can be laminated with a laminating layer that is uniformly adhered to the recording surface and whose edge is along the edge of the recording medium.

As another aspect, the roller that receives the biasing force by the pressure roller via the laminate material and the recording medium may constitute a transfer-receiving means to which the laminate layer protruding from the recording medium is transferred. . In this case, the laminate layer of the laminate material is adhered to the entire recording surface of the recording medium by thermocompression bonding the laminate material to the recording medium, and the portion protruding from the recording surface is transferred to the recording means. It adheres closely to the outer peripheral surface of the roller.

  In this state, when the roller rotates and the outer peripheral surface (transferring means) of the roller tends to be separated from the surface opposite to the recording surface of the recording medium, the laminate layer in close contact with the roller is opposite to the recording medium. At this time, the pulling force is concentrated along the boundary between the portion where the recording medium is present and the portion where the recording medium is absent (that is, the edge of the recording medium). Therefore, the portion where the laminate layer and the recording surface are pressure-bonded (laminate portion where the laminate layer is laminated on the recording surface) and the portion where the laminate layer and the roller itself are pressure-bonded (not laminated on the recording medium) Of course, the edge of the laminate layer formed on the recording surface of the recording medium becomes clean along the edge of the recording medium. Therefore, when the laminating process is performed by the laminating apparatus, the recording surface of the recording medium can be laminated with a laminating layer that is uniformly adhered to the recording surface and whose edge is along the edge of the recording medium.

  As described above, the present invention is configured to heat and pressure-bond the laminate material and the recording surface while heating the laminate material superimposed on the recording surface of the sheet-like recording medium by the urging force. In the laminating apparatus according to the present invention, the pressure roller is formed to have a drum shape as the outer diameter decreases from the substantially central portion in the axial direction toward both ends, and is elastically deformed by the biasing force. Even if the laminate material is heated and pressed with a pressure roller supported at both ends while the laminate material is heated and pressure-bonded to the recording surface of the recording medium, the lamination material and the recording surface of the recording medium can be made uniform. Thermocompression can be performed, and the quality of the finish can be improved.

  Hereinafter, a laminating apparatus according to an embodiment of the present invention will be described with reference to the drawings.

<First embodiment>
First, an appearance image of the laminating apparatus according to the present embodiment will be briefly described with reference to FIGS. The laminating apparatus includes various functional units (which will be described later) in the housing 1, and a recording medium supply unit (supplying unit) that supplies the recording medium A for which image recording has been completed for laminating processing. 10 is provided on one side of the casing 1, and a finished product discharge section (discharge section) 150 that discharges the recording medium A that has been laminated is provided on the other side of the casing 1.

  The housing 1 includes side frames 1a and 1b arranged on the left and right sides, and a connecting frame 1c that is arranged at an appropriate position between the side frames 1a and 1b and connects the side frames 1a and 1b at a predetermined interval. Become. The side frames 1a and 1b are divided into upper and lower parts, respectively, and the upper side frame 1a and 1b and the connecting frame 1c for connecting the upper frame 1A constitute the upper casing 1A, while the lower side frame 1a and 1b. A lower housing 1B is configured by 1a, 1b and a connecting frame 1c connecting them.

  Therefore, the housing 1 can be separated vertically. More specifically, a part 1d of the upper housing 1A is rotatably supported by the lower housing 1B and swings so as to be openable and closable with respect to the lower housing 1B. A lock mechanism 2 is provided in the housing 1 in order to maintain a closed position where the upper housing 1A and the lower housing 1B are combined.

  The recording medium supply unit 10 includes a mounting plate 11 attached to a boundary portion between the upper housing 1A and the lower housing 1B on one side of the housing 1. On the other hand, the finished product discharger 150 also includes a mounting plate 151 attached to a boundary portion between the upper housing 1A and the lower housing 1B on the other side of the housing 1. The mounting plate 11 is rotatably attached to the upper housing 1A, and takes a horizontal position where the recording medium A can be mounted and a vertical position where the recording medium A cannot be mounted. The mounting plate 151 is fixedly attached to the lower housing 1B. It should be noted that a pair of width regulating guides that are relatively close to each other in the width direction is provided on the mounting plate 11 so that the center of the recording medium A is always aligned regardless of the width size of the recording medium A. preferable.

  The transport path of the recording medium A that connects the recording medium supply unit 10 and the finished product discharge unit 150 is the same as the placement plate 11 of the recording medium supply unit 10 and the placement plate 151 of the finished product discharge unit 150. It is set along the boundary between the upper casing 1A and the lower casing 1B. Therefore, the transport path is opened at the open position where the upper casing 1A is swung upward, and the recording medium A on the transport path can be taken out.

  As shown in FIG. 3 and FIG. 4, the functional unit is roughly divided from the recording surface (upper surface) side of the recording medium A conveyed on the conveyance path, and the base material C and the laminate layer as a base are laminated. A laminate material supply unit (supply unit) 20 that supplies the sheet-like laminate material B and a surface (lower surface: base surface) opposite to the recording surface of the recording medium A conveyed on the conveyance path are transferred. An under film supply unit (supply unit) 30 that supplies a sheet-like under film E as a means, and a laminate in which the recording medium A is supplied and stacked between the supplied laminate material B and the under film E ( First and second pressure-bonding parts (pressure-bonding parts) 40 and 50 for heat-pressing the recording medium A between the laminate material B and the under film E), and the laminate material B after the heat-pressure bonding Remove substrate C from Peeling part 60 for separating, base material collecting part (collecting part) 70 for collecting the peeled base material C, separating part 80 for separating the underfilm E after thermocompression bonding from the recording medium A, and the separated under The film E is divided into an under film collection unit (collection unit) 90 that collects the film E.

  As shown in FIG. 5, the laminate material supply unit 20 supplies the laminate material B as a continuous sheet from a roll, and includes a holder (laminate material holder) 21 that holds the roll of the laminate material B. 21 and a free roller 22 disposed between the conveyance path.

  Both ends of the holder 21 are rotatably supported by the side frames 1a and 1b together with the free roller 22. The free roller 22 is disposed so as to be on the inner side (conveying path side) of the roll attached to the holder 21 and the common tangent line of the roller 43 of the press-bonding section described later, thereby conveying the laminate material B fed from the roll. Wrapping is performed in a predetermined angle range in a predetermined section until reaching the path, and the approach angle of the laminate material B with respect to the transport path is determined. In addition, the free roller 22 is disposed in a region that can be affected by heat from the pressure roller 43 of the first pressure-bonding portion 40 serving as a heating roller, as will be described later. The material used for at least the surface of the free roller 22 is black alumite, which has a relatively excellent heat absorption rate and heat conductivity.

  A laminating material B used in the laminating apparatus of this embodiment includes a laminating layer D for laminating the recording surface of the recording medium A as shown in FIG. The laminate layer D has a laminated structure including an adhesive layer D ′ that adheres to the recording surface and a protective layer D ″ that is formed on the adhesive layer D ′ and protects the recording surface. The protective layer D ″ according to the present embodiment is formed of a transparent acrylic resin. The adhesive layer D ′ is laminated with the protective layer D ″ via a joint anchor coat layer D ″ ′ having transparency so as to maintain adhesiveness with the protective layer D ″. The adhesive layer D ′ has a higher adhesive force to the under film E than the adhesive force of the base material C to the protective layer D ″ and has permeability (in this embodiment, it is bonded by applying heat). A thermoplastic resin that exhibits strength: a polyester-based resin).

  Furthermore, the laminate material B is used to prevent the laminate layer D from being scratched during thermocompression bonding and transportation, and to prevent the laminate layer D from being wrinkled during thermocompression bonding (protective layer D ′). ') A sheet-like substrate C is laminated on D so as to be peelable. That is, by laminating the base material C on the laminate layer D, the laminate material B prevents the surface of the laminate layer D from being scratched and gives the laminate material B itself stiffness (thickening the thickness). The degree of freedom of bending in the laminate material B is reduced), and the occurrence of wrinkles in the laminate layer D due to the influence of pressure or the like during thermocompression bonding can be prevented. The base material C is composed of a film made of polyethylene terephthalate (PET), and is in close contact with the laminate layer (protective layer D ″) D so as to be peelable by its own adhesiveness. And a laminated structure.

  The laminate material B having the above configuration is larger in size than the recording medium A, that is, in a state where the laminate layer D is opposed to the recording surface of the recording medium A, the recording material is recorded with the laminate material B (laminate layer D). A size that can cover A is set. In the present embodiment, as described above, since the laminate material B is long, when the laminate material B covers the recording medium A in a state of protruding from both the vertical and horizontal directions of the recording medium A, the direction is conveyed (conveyance). The size of the travel direction in the path does not matter, and the width (the dimension in the direction orthogonal to the travel direction in the transport path) is set wider than the width of the recording medium A on the transport path. Therefore, the recording medium A does not protrude from the laminating material B in the width direction even when the recording medium A is parallel to the transport direction, or even when it is slightly inclined. The entire surface of the recording medium A can be reliably covered with the material B (laminate layer D). The roll of the laminate material B having the above configuration is wound so that the base material C faces the outside and the laminate layer D faces the inside, so that the base material C contacts the free roller 22. It is like that.

  On the other hand, returning to FIG. 5, the under film supply unit 30 supplies the under film E from the roll as a continuous sheet, and includes a holder (under film original fabric holder) 31 that holds the roll of the under film E, A free roller 32 is provided between the holder 31 and the conveyance path.

  Both ends of the holder 31 are rotatably supported by the side frames 1a and 1b together with the free roller 32. The free roller 32 conveys the under film E fed out from the roll by being arranged so as to be on the inner side (conveyance path side) of the roll attached to the holder 31 and the common tangent line of the roller 41 of the pressure-bonding section described later. Wrapping is performed in a predetermined angle range in a predetermined section until reaching the path, and an approach angle of the under film E with respect to the transport path is determined. In addition, the free roller 32 is disposed in a region that can be affected by heat from the drive roller 41 of the first pressure-bonding portion 40 that is a heating roller, as will be described later. The material used for at least the surface of the free roller 32 is black alumite, which has a relatively excellent heat absorption rate and heat conductivity, like the free roller 22.

  The under film E functions as a transfer material serving as a base in a laminated state, and is made of a material having thermal adhesiveness with the adhesive layer D ′ of the laminate material B or a material having the same quality as the adhesive layer D ′. A resin film is used. The under film E can employ either a single layer structure or a laminated structure, but in the present embodiment, a single layer film made of PET (polyethylene terephthalate) is employed. The under film E has a width size equal to or greater than that of the laminate material B so that the laminate material B (laminate layer D) does not protrude from the side edge of the under film E in a laminated state. Is used.

  The first pressure bonding part 40 includes a driving roller 41 and a pressure roller 43 that are rollers. The driving roller 41 is disposed on the base surface side of the recording medium A, and the pressure roller 43 is disposed on the recording surface side of the recording medium A, and both ends thereof are rotatably supported by the side frames 1a and 1b. And are provided so that their axis centers are substantially parallel to each other. Between the rollers 41 and 43, the laminate material B, the under film E, and the recording medium A supplied from the recording medium supply unit 10 are laminated (hereinafter referred to as recording medium A, laminating material B (laminate material). B) and layers in which at least two of the under films E are laminated are collectively referred to as “laminated body”).

  Both rollers 41 and 43 generate a pressure-bonding action on the laminate (A + B + E). For example, the drive roller 41 is a metal roller or an ultra-thin rubber roller, and the pressure roller 43 is a silicon-based roller. The heat-resistant rubber roller is used.

  Further, both rollers 41 and 43 have heaters 42 and 44 at the shaft core portions and are heating rollers. The heating temperature on the surfaces of the rollers 41 and 43 is set in the range of 60 to 120 ° C. for the driving roller 41, and is set in the range of 80 to 120 ° C. for the pressure roller 43. The driving roller 41 is supplied from the under film supply unit 30 before the point (theoretical contact point between the rollers 41 and 43) where the recording medium A, the laminate material B, and the under film E are heat-pressed. The under film E is disposed so as to be wound at a predetermined angle so that the under film E can be preheated before reaching the thermocompression bonding point. Further, the pressure roller 43 is arranged so that the laminate material B supplied from the laminate material supply unit 20 is wound at a predetermined angle before the heat pressure point, and reaches the heat pressure point. It can be preheated prior to. In addition, since the free rollers 22 and 32 are heated by receiving heat from the rollers 41 and 43, they also have a function as a heating roller, and the laminating material B and the under film E preheat the rollers 41 and 43. Prior to this, the free rollers 22 and 32 are also preheated. In addition, the roller (driving roller) 41 on the under film E side in the first pressure-bonding part 40 is also set as a heating roller and lower than the heating temperature on the roller surface of the roller (pressure-bonding roller) 43 on the laminate material B side. This is for activating the heat-welding property between the laminate layer D and the under film E while suppressing the thermal influence on the under film E.

  Further, the drive roller 41 cannot be displaced relative to the side frames 1a and 1b, whereas the pressure roller 43 is connected to the side frames 1a and 1b (and the drive roller 41) via the pressure force adjusting mechanism 45. On the other hand, relative displacement is possible. The crimping force adjusting mechanism 45 includes a base 450 attached to the side frames 1a and 1b, a shaft 451 attached to the base 450 and having an axis in a direction perpendicular to the conveyance path, and slides along the shaft 451. A movable body 452, an elastic body 453 that biases the movable body 452 toward the conveyance path, and a handle (adjusting member) 454 that adjusts the elastic restoring force of the elastic body 453.

  Both ends of the pressure roller 43 are pivotally supported by a pressure adjusting mechanism 45 (movable body 452), and an urging force acts in a direction orthogonal to the axis of the pressure roller 43 (toward the conveyance path). It has become. As shown in FIG. 6, the pressure roller 43 has an outer diameter that decreases in the axial direction from the center toward both ends, and the outer shape is formed in a drum shape. In addition, the pressure roller 43 has an outer peripheral surface when the shaft body of the pressure roller 43 is bent while the pressure roller 43 is in pressure contact with the driving roller 41 and a rubber roller is used as described above. Is configured to be elastically deformed. As a result, the pressure roller 43 is surely brought into contact with the laminate material B in a linear or belt-like region extending in the axial direction on the outer peripheral surface.

  In the present embodiment, the drive roller 41 also has an outer diameter that decreases in the axial direction from the center to both ends in the axial direction, and the outer shape is formed in a drum shape. By forming the drum like this, when the urging force by the pressure adjusting mechanism 45 acts on the drive roller 41 via the pressure roller 43, the shaft body and the outer peripheral surface of the drive roller 41 are elastically deformed. The outer peripheral surface of the pressure roller 43 can be uniformly contacted (see FIG. 6). That is, as shown in FIG. 7, when the urging force F of the pressure adjusting mechanism 45 acts on both ends of the pressure roller 43, the central portions where the outer diameters of the pressure roller 43 and the drive roller 41 are thicker than both ends are in contact with each other. A reaction force or the like against the urging force F acts to relatively deflect the shafts of the drive roller 41 and the pressure roller 43, and the outer peripheral surfaces of the drive roller 41 and the pressure roller 43 are elastically deformed. The outer peripheral surfaces of 41 are in uniform contact over the entire length. Thus, the laminate material B and the recording medium A interposed between the driving roller 41 and the pressure roller 43 can be evenly pressure-bonded. In this embodiment, the pressure-bonding force between both rollers 41 and 43 is set within a range of 50 to 120 kgf, and both rollers 41 and 43 have their respective shaft bodies when the pressure-bonding force acts within this range. The shaft strength is set so that the

  As shown in FIG. 8, the second pressure bonding part 50 includes a driving roller 51 and a pressure roller 53 that are rollers. The drive roller 51 is disposed on the base surface side of the recording medium A, and the pressure roller 53 is disposed on the recording surface side of the recording medium A, and both ends thereof are rotatably supported by the side frames 1a and 1b. And are provided so that their axis centers are substantially parallel to each other. In the laminate (A + B + E), the base material C is peeled off at the peeling portion 60 located on the upstream side of the transport path from the second crimping portion 50, so that the laminate (A + B + E−) is between the rollers 51 and 53. C) is supplied.

  Both rollers 51 and 53 cause a pressure-bonding action to the laminated body (A + B + E-C). For example, a silicon-based heat-resistant rubber roller is used for both the driving roller 51 and the pressure roller 53.

  Further, the pressure roller 53 has a heater 54 in the shaft core portion, and is a heating roller. The heating temperature on the roller surface is set within a range of 80 to 120 ° C. The drive roller 51 is not a heating roller. The heating temperature in the second press-bonding section 50 (heating temperature by the press-bonding roller 53) has a meaning in terms of finishing processing, and the heating temperature in the first press-bonding section 40 (total heating temperature in the driving roller 41 and the press-bonding roller 43). Set lower than. That is, for example, when bubbles are mixed between the recording medium A and the laminate layer D, if the pressure is applied without heating, the pressure is applied in a state where the adhesive layer D ′ of the laminate layer D is cured. Therefore, the air bubbles cannot be pushed in well, but when heated, the adhesive layer D ′ is softened, and the pressure is applied in that state, so that the air bubbles are pushed into the recording surface of the recording medium A from the gap of the ink. For the reason that the laminate layer D (adhesive layer D ′) is displaced from the recording surface of the recording medium A or peeled off when the heating temperature is too high, the second pressure-bonding portion 50 is removed. However, while heating, the heating temperature in the second crimping part 50 is set lower than the heating temperature in the first crimping part 40. Further, the reason why the driving roller 51 of the second pressure-bonding part 50 is not a heating roller is that the heating temperature in the second pressure-bonding part 50 is not excessively raised as described above, and the once heated laminate is heated again. If the temperature is too high, the quality of the recording medium A and the laminate layer D may be deteriorated, the heater is eliminated and the manufacturing cost is reduced, and the running cost is reduced by reducing the power consumption. In addition, the crimping force in the second crimping part 50 is set to be smaller than the crimping force in the first crimping part 40 due to the absence of the base material C.

  Similarly to the first pressure-bonding portion 40, the drive roller 51 cannot be displaced relative to the side frames 1a and 1b, whereas the pressure-bonding roller 53 is connected to the side frames 1a and 1b via the pressure-bonding force adjusting mechanism 55. Relative displacement with respect to 1b (and drive roller 41) is possible. In addition, since the structure of the crimping | compression-bonding force adjustment mechanism 55 is the same as that of the crimping | compression-bonding force adjustment mechanism 45 of the 1st crimping | compression-bonding part 40, it does not explain in particular.

  Further, the pressure roller 53 of the second pressure bonding part 50 is pivotally supported by the pressure adjusting mechanism 45 (movable body 452) at both ends, similarly to the pressure roller 43 of the first pressure bonding part 40. An urging force is applied in a direction orthogonal to the axis (toward the transport path). The pressure roller 43 has an outer diameter that decreases in the axial direction from the center toward both ends, and has an outer shape that is a drum shape. (See FIG. 6). Further, the pressure roller 53 has an outer peripheral surface when the shaft body of the pressure roller 53 is bent while the pressure roller 53 is in pressure contact with the driving roller 51 and the rubber roller is used as described above. Is configured to be elastically deformed. Thereby, the pressure roller 53 is configured so that the linear or belt-like region extending in the axial direction on the outer peripheral surface comes into contact with the laminate material B with certainty.

  In the present embodiment, the drive roller 51 also has an outer diameter that decreases in the axial direction from the center to both ends in the axial direction, and the outer shape is formed in a drum shape (see FIG. 6). By forming the drum like this, when the urging force by the pressure adjusting mechanism 55 acts on the drive roller 51 via the pressure roller 53, the shaft body and the outer peripheral surface of the drive roller 51 are elastically deformed. Thus, the outer peripheral surface of the pressure roller 53 can be uniformly contacted. That is, when the urging force F of the pressure adjusting mechanism 55 acts on both ends of the pressure roller 53 as in the first pressure bonding portion 40, the central portions where the outer diameters of the pressure roller 53 and the driving roller 51 are thicker than the both ends are formed. The shafts of the drive roller 51 and the pressure roller 53 are relatively bent due to the contact force and the reaction force against the biasing force F, and the outer peripheral surfaces of the drive roller 51 and the pressure roller 53 are elastically deformed. And the outer peripheral surfaces of the driving roller 51 are in uniform contact over the entire length (see FIG. 7). Thus, the laminate material B and the recording medium A interposed between the driving roller 51 and the pressure roller 53 can be evenly pressure-bonded. In this embodiment, the pressing force between the rollers 51 and 53 is set within a range of 50 to 120 kgf, and both rollers 51 and 53 have their respective shaft bodies when the pressing force acts within this range. The shaft strength is set so that the

  The peeling part 60 is disposed between the first pressure bonding part 40 located on the upstream side of the conveyance path and the second pressure bonding part 50 located on the downstream side of the conveyance path with respect to the first pressure bonding part 40, and the conveyance path. Is provided with a knife edge (peeling guide body) 61 disposed to face the surface.

  That is, the peeling part 60 is a position at a predetermined distance downstream from the first pressure-bonding part 40 so as to separate the base material C from the laminate layer D after a predetermined time has elapsed since the first pressure-bonding part 40 is heat-bonded. Is provided with a knife edge 61. Thus, the peeling part 60 is disposed at a predetermined distance from the first pressure bonding part 40 because the laminate is activated (exhibits viscosity, etc.) by being heat-pressed by the first pressure bonding part 40. This is because an external force is applied to the laminate material B (laminate layer D) after the layer D reaches a normal equilibrium state (a state in which the adhesive force is increased).

  That is, when a predetermined time elapses from the heating in the first pressure bonding part 40, the adhesive force of the laminate layer D to the recording medium A is surely increased as compared with the adhesive force between the base material C and the laminate layer D. If the peeling process of the base material C is performed in the state, only the base material C is peeled cleanly without the laminate layer D being carelessly peeled off from the recording medium A, so that the distance between the peeling part 60 and the first pressure bonding part 40 is increased. Provided. Therefore, the interval (predetermined distance) between the peeling part 60 and the first pressure bonding part 40 is such that the time from passing through the first pressure bonding part 40 to reaching the peeling part 60 is approximately normal from the active state of the laminate layer D. It is set so that it substantially coincides with or exceeds the time (predetermined time) required to return to the equilibrium state.

  The knife edge 61 is held by the holder 62 so that the tip end portion thereof becomes the transport path side and is inclined at an acute angle with respect to the transport path. More specifically, the knife edge 61 is connected to the lower surface 61a facing the conveyance path in the peeling unit 60 and the downstream edge of the lower surface 61a in the conveyance direction so as to form an acute angle with the lower surface 61a. And an inclined surface 61b extending upward (extending toward the base material recovery unit 70). Further, a connecting line (ridge line) between the lower surface 61a and the inclined surface 61b extends in a direction substantially orthogonal to the transport direction of the recording medium A on the transport path.

  Further, the peeling portion 60 further includes a guide plate 63 having a guide surface facing the inclined surface 61b as a guide surface of the knife edge 61 with a predetermined distance, and a continuous sheet-like base peeled from the laminate layer D is provided. The material C is sent to the base material collection unit 70 through the inclined surface 61 b of the knife edge 61 and the guide surface of the guide plate 63.

  The base material collection unit 70 collects the continuous sheet-like base material C peeled off from the laminate layer D in a roll shape, and a holder (recovered base material holder) 71 that holds the roll of the base material C. Is provided. Both ends of the holder 71 are rotatably supported by the side frames 1a and 1b. Further, the holder 71 is disposed so that the winding surface is on the upstream side of the conveyance path with respect to the leading edge of the knife edge 61, whereby the substrate C to be peeled from the conveyance path is removed from the leading edge of the knife edge 61. In addition, the peeling angle of the base material C with respect to the conveyance path is determined.

  As shown in FIG. 9, the separation unit 80 is located downstream of the crimping unit (second crimping unit 50) in the transport path (more specifically, the second crimping unit 50 and the laminate (A + B-C: finished product)). And a knife edge (separation guide body) 81 disposed between the pair of transport rollers 100 for transporting the finished product to the finished product discharge section 150 and disposed facing the transport path.

  That is, the separation unit 80 places a predetermined distance downstream from the second pressure-bonding part 50 in order to separate the under film E from the recording medium A after a predetermined time has passed since the second pressure-bonding part 50 was heat-bonded. A knife edge 81 is provided at the position. Thus, the separation part 80 is disposed at a predetermined distance from the second pressure bonding part 50 because the laminate is activated (exhibits viscosity, etc.) by being heat-pressed by the second pressure bonding part 50. This is because an external force is applied to the laminate material B (laminate layer D) after the layer D reaches a normal equilibrium state (a state in which the adhesive force is increased).

  That is, when a predetermined time elapses from the heating in the second pressure bonding part 50, the adhesive force of the laminate layer D to the recording medium A is surely increased. Since the layer D is not inadvertently peeled off from the recording medium A, an interval between the separation unit 80 and the second pressure bonding unit 50 is provided. Accordingly, the interval (predetermined distance) between the separating portion 80 and the second crimping portion 50 is such that the time from passing through the second crimping portion 50 until reaching the separating portion 80 is approximately normal from the active state of the laminate layer D. It is set so that it substantially coincides with or exceeds the time (predetermined time) required to return to the equilibrium state.

  3 and 4, the distance from the second crimping part 50 to the separating part 80 is shorter than the distance from the first crimping part 40 to the peeling part 60. In addition to the heating temperature in the second crimping part 50 being set lower than the temperature, the laminate (A + B + E) passing on the transport path between the first crimping part 40 and the peeling part 60 is naturally cooled. On the other hand, between the second crimping part 50 and the separating part 80 (actually, across the upstream and downstream sides of the conveying path across the tip of the separating part 80 (knife edge 81)) A plate-shaped guide plate 83 is provided, which improves the transportability of the laminate (A + B + EC) and forcibly releases the heat of the laminate (A + B + EC) ( With forced cooling) This is because is functioning Te. And since the distance from the 2nd crimping | compression-bonding part 50 to the isolation | separation part 80 becomes short, size reduction of the whole apparatus can be achieved. In the present embodiment, the interval between the separation part 80 and the second pressure bonding part 50 is such that the time from passing through the second pressure bonding part 50 until reaching the separation part 80 is determined so that the laminate layer D is in the active state. Based on the correlation between the moving speed of the laminated body (A + B + E−C) on the conveyance path, the cooling efficiency of the guide plate 83, and the like so as to be the time (predetermined time) required to return to a substantially normal equilibrium state. Is set.

  Returning to FIG. 9, the knife edge 81 is held by the holder 82 so that the tip portion thereof becomes the transport path side and is inclined at an acute angle with respect to the transport path. Specifically, the knife edge 81 of the separation unit 80 is connected to the upper surface 81a facing the conveyance path in the separation unit 80 and the downstream edge of the upper surface 81a in the conveyance direction. And an inclined surface 81b extending downward to form an acute angle. In addition, a connecting line (ridge line) between the upper surface 81a and the inclined surface 81b extends in a direction substantially perpendicular to the transport direction in the transport path.

  In addition, the separating unit 80 includes the guide plate 83 that is built in the housing 1 in order to demarcate the conveyance path and has a shape straddling the upstream side and the downstream side of the conveyance path across the tip of the knife edge 81. . More specifically, the guide plate 83 has a distal end portion extending to the vicinity of the compression portion (second compression portion 50), and a base end portion of the guide plate 83 beyond the distal end portion of the knife edge 81 on the downstream side of the conveyance path. It is the shape extended to. Further, the separating unit 80 includes a guide plate 84 having a guide surface facing the inner surface (guide surface) of a portion of the guide plate 83 on the downstream side of the conveyance path from the tip of the knife edge 81 with a predetermined distance. Is further provided.

  Both guide plates 83 and 84 are bent at a predetermined angle in a direction in which a tip end portion (an end portion on the upstream side of the transport path) is separated from the transport path to form a tapered and widened inlet side opening. The guide plate 84 is offset in a direction away from the transport path with respect to the upper surface 81a of the knife edge 81, and is set at a lower position than the upper surface 81a of the knife edge 81. The guide surface interval is wider than the interval between the guide surface of the guide plate 83 and the upper surface 81 a of the knife edge 81. That is, the guide surface interval that defines the conveyance path on the downstream side of the knife edge 81 is set wider in the direction after separation than before the under film E is separated.

  The under film collection unit 90 collects a continuous sheet of the under film E, onto which the extra laminate layer D has been transferred, by rolling it into a roll. A holder for holding the roll of the under film E (collected under film holding body) 91 is provided. Both ends of the holder 91 are rotatably supported by the side frames 1a and 1b. Further, the holder 91 is disposed such that the winding surface is on the upstream side of the conveyance path with respect to the tip end (ridge line) of the knife edge 81, whereby the under film E separated from the conveyance path is removed from the knife edge 81. And the peeling angle of the base material C with respect to the conveyance path is determined.

  The configuration of each functional unit is as described above. Returning to FIGS. 1 to 4, the main components of the laminate material supply unit 20, the peeling unit 60, and the base material recovery unit 70 are the same housing (upper housing 1 </ b> A located on the recording surface side of the recording medium A). On the other hand, the main components of the under film supply unit 30, the separation unit 80, and the under film collection unit 90 are also arranged in the same casing (the lower casing 1B located on the base surface side of the recording medium A). ing. Moreover, the 1st crimping | compression-bonding part 40, the 2nd crimping | compression-bonding part 50, and the conveyance roller pair 100 are arrange | positioned ranging over both housings | casings (upper housing | casing 1A and lower housing | casing 1B).

  Further, the driving rollers 41, 51, 101 of the first pressure-bonding portion 40, the second pressure-bonding portion 50, and the conveying roller pair 100 are arranged in one housing (lower housing 1B), and are respectively pressure-bonding rollers (driven rollers). 43, 53, 102 are arranged in the other casing (upper casing 1A).

  Further, not only the first pressure-bonding portion 40, the second pressure-bonding portion 50, and the drive rollers 41, 51, 101 of the conveying roller pair 100 but also all of the holders 71, 91 of the base material collecting portion 70 and the under film collecting portion 90. , Sprockets, chains, gear trains, and other known driving force transmission means (see FIGS. 1 and 2; however, the number is not assigned since the configuration is clear from the drawings). It is to be transmitted. By these synchronous drives, the laminate material B is pulled from the laminate material supply unit 20, the under film E is pulled from the under film supply unit 30, and the laminate (A + B + E; A + B + E−C; A + B−C) is in the conveyance path. It is conveyed along the downstream side.

  However, in order to convey a thin film such as the laminate material B (laminate layer D thereof), the driving roller 51 of the second pressure bonding section 50 is overdriven by 3% or less than the driving roller 41 of the first pressure bonding section 40. Thus, a back tension is applied to the laminate material B between the compression portions 40 and 50. The reason why the content is 3% or less is that when the back tension is too small, a slack is generated between the first and second pressure-bonding portions 40 and 50, and the recording medium A is distorted or softened by heating. W is generated on the recording surface of the recording medium A. On the other hand, if the back tension is too large, the laminate layer D is extended by the back tension and vertical wrinkles are generated. This is because vertical wrinkles also appear on the recording surface of the recording medium A.

  The laminating apparatus according to this embodiment is configured as described above. Next, each step of the laminating process in the apparatus will be described.

  First, before performing the laminating process on the recording medium A, the laminating material B is pulled out from the laminating material supply unit 20 in advance, and the laminating material B is wound around the free roller 22 to be bonded to the first pressure bonding unit 40 (the driving roller 41 and the pressure bonding). Between the roller 43) and the second pressure bonding part 50 (between the driving roller 51 and the pressure roller 53), and the tip is wound around the holder 71 of the base material recovery part 70. Further, the under film E is pulled out from the under film supply unit 30, and the under film E is wound around the free roller 32, and the first pressure bonding unit 40 (between the driving roller 41 and the pressure roller 43) and the second pressure bonding unit 50 ( The tip portion is wound around the holder 91 of the under film collecting unit 90. In this state, the laminate material B and the under film E are overlapped on the conveyance path between the first crimping portion 40 and the separation portion 60.

  In this state, as shown in FIG. 5, the recording surface of the recording medium A is directed to the side to which the laminate material B is supplied (in this embodiment, the upper side corresponding to the arrangement of the laminate material supply unit 20), The recording medium A is sequentially supplied from the recording medium supply unit 10. That is, the laminating apparatus can continuously laminate a plurality of recording media A, with a gap between the preceding recording medium A and the succeeding recording medium A. The recording medium A is sequentially supplied from the recording medium supply unit 10. Then, each recording medium A that is sequentially supplied is in a state of being interposed between the laminating material B and the under film E with the recording surface and the laminating layer D facing each other. The recording medium A and the under film E are heat-pressed. Thus, since the laminate material B is supplied so as to protrude from both end edges in the conveyance direction and the width direction of the recording medium A, the laminate layer D softens and is recorded when it is heat-pressed by the first pressure-bonding portion 40. It is deformed so as to cover the recording surface and end surface of the medium.

  Then, as described above, since the laminate material B and the under film E are set to a size larger than the recording medium A, the recording medium A is sandwiched between the laminate material B and the under film E, and FIG. As shown in FIG. 4, the laminate layer D is transferred to the under film E so that the laminate layer D protrudes from the recording medium A, and the laminate layer Da adheres to the recording surface of the recording medium A, and the recording medium of the laminate part Da A non-laminate portion Db in which the laminate layer D is in close contact with the under film E so as to surround A is formed.

  That is, as shown in FIG. 11B, the laminate material B, the recording medium A, and the under film E are heat-pressed at the first pressure bonding portion 40 (the three members of the laminate material B, the recording medium A, and the under film E are Pass through the first press-bonding portion 40), a recording medium A, a laminating portion B in which the laminating material B and the under film E are laminated, and a non-laminating portion Db in which the laminating material B and the under film E are laminated. A laminated body (A + B + E, B + E) is obtained. The transfer width Db of the laminate layer D transferred to the under film E is set to about 3 mm or more. If it is smaller than this value, the adhesive area between the under film E and the laminate layer D is small and the adhesive force is not sufficient, so the under film E and the laminate layer D may be peeled off. This is because the portion (laminate portion) Da where the layer D and the recording surface are pressure-bonded and the portion (non-laminate portion) Db where the laminate layer D and the under film E are pressure-bonded may not be separated cleanly.

  Next, the laminate (A + B + E, B + E) obtained in the first pressure bonding part 40 is conveyed to the peeling part 60 as shown in FIG. Since the laminate (A + B + E, B + E) is heated in the first pressure bonding part 40 and is in a state of being cooled to some extent as time (predetermined time) elapses, the adhesive layer D ′ of the laminate layer D is Curing has started (returning from the active state to the normal equilibrium state), and as a result, the adhesive layer D ′ has been substantially cured or has been cured to some extent (substantially normal equilibrium state) and has reached the peeling portion 60. In the laminate (A + B + E, B + E), the adhesion between the base material C and the laminate layer D is greater than the adhesion between the laminate layer D and the recording surface of the recording medium A and the adhesion between the laminate layer D and the under film E. (The adhesion force between the laminate layer D and the recording surface of the recording medium A and the adhesion force between the laminate layer D and the under film E are larger than the adhesion force between the substrate C and the laminate layer D). Therefore, even if the base material C is pulled upwards in the conveying direction via the knife edge 61, only the base material C is reliably peeled off, and one of the laminating layers D is as in the conventional laminating apparatus. Part or all is not taken away with the base material C.

  Moreover, in the peeling portion 60, the tip of the knife edge 61 is in sliding contact with the laminate (A + B + E), so that the laminate (A + B + E) is prevented from being lifted due to the peeling of the substrate C, and the substrate C is peeled off. The angle is stabilized.

  Next, the laminate (A + B + E-C) from which the substrate C has been peeled off at the peeling portion 60 is conveyed to the second pressure bonding portion 50 where the second thermocompression bonding is performed. As described above, the laminating apparatus according to the present embodiment employs a configuration in which the base material C is first heat-pressed in the presence of the base material C, and then the base material C is removed. The adhesion of the laminate layer D to the recording surface of the recording medium A can be improved, and even if, for example, bubbles are mixed between the recording medium A and the laminate layer D at the time of lamination at the first pressure-bonding portion 40. By removing these bubbles, a clean finished surface can be obtained.

  Next, the laminated body (A + B + E−C) subjected to the second thermal compression bonding at the second pressure bonding unit 50 is conveyed to the separation unit 80 as shown in FIG. In the laminate (A + B + E-C), the laminate layer D of the laminate material B is activated again by the thermocompression bonding at the second crimping portion 50, but the time after the thermocompression bonding at the second crimping portion 50 ( The adhesive layer D ′ of the laminate layer D is cured (returning from the active state to the normal equilibrium state) with the natural heat dissipation due to the elapse of a predetermined time and the forced cooling due to the heat dissipation action of the guide plate 83. Will move towards. As a result, the laminate (A + B + E-C) reaches the separation portion 80 in a state where the adhesive layer D ′ is substantially cured or cured to some extent (approximately normal equilibrium state), where the under film E is separated. Is done.

  Thus, the laminated body (A + B + E−C) having reached the separating portion 80 with the adhesive layer D ′ in a substantially normal equilibrium state moves downstream while sliding on the upper surface of the knife edge 81 of the separating portion 80. When passing through the ridgeline of the knife edge 81, the underfilm E is wound around the holder 91 of the underfilm collection unit 90 with the underfilm E being wound around the tip of the knife edge 81. At this time, as shown in FIG. 12, the recording medium A and the under film E move relative to each other so that the base surface of the recording medium A and the under film E are separated from each other. In other words, the recording medium A tends to move further between the guide plates 83 and 84 (conveyance path) toward the downstream side, whereas the under film E has a direction (that is different from the moving direction of the recording medium A). (The direction away from the base surface of the recording medium A). Therefore, since the laminate layer D of the non-laminate portion Db from which the substrate C has been peeled also tends to move in the same direction as the under film E, the boundary between the portion with the recording medium A and the portion without the recording medium A (that is, the non-laminate portion) The tensile force acts intensively at the boundary between Db and the laminate portion Da. As a result, only the non-laminate portion Db is surely cut away, and the edge of the laminate portion Da becomes clean along the edge of the recording medium A.

  One reason that the edge of the laminated portion is finished cleanly is considered to be that the edge of the recording medium A exhibits a function like a cutting blade. That is, the boundary between the laminated portion Da and the non-laminated portion Db is caused by the edge of the recording medium A due to the shearing force (when the under film E is separated, the reaction force of the edge of the recording medium A and The laminating layer Da and the non-laminating portion Db are covered with each other by the interaction of the adhesion of the non-laminating portion Db with the under film E due to the interaction between the laminating layer D and the non-laminating portion Db. It is cut along the edge of the recording medium A. In particular, since the knife edge 81 according to the present embodiment has an acute angle between the upper surface and the inclined surface, the under film collection unit 90 is determined from the moving direction of the under film E on the transport path and the tip (ridge line) of the knife edge 81. Since the moving direction of the under film E moving toward the head is an acute angle, it is considered that the edge of the recording medium A functions as a very sharp cutting blade.

  Alternatively, as another reason, the minimum width region of the laminate layer D along the edge of the recording medium A is caused by the thickness of the recording medium A as shown in FIG. It is thought that it is in a slightly floating state. Since the pulling force when separating the under film E acts on the floating portion intensively, the laminate layer D is broken at the floating portion, and the laminated portion Da and the non-laminated portion Db are formed on the recording medium A. It is cut along the edge. Alternatively, as another reason, the laminate material B and the under film E which are set to a size larger than the recording medium A are used, and the laminate material B is bonded to the laminate material B by the crimping portions 40 and 50 with the recording medium A interposed. In order to thermocompression bond with the under film E, the laminate layer D of the laminate B is deformed along the shape of the recording surface and the edge of the recording medium A, and as a result, the edge of the recording medium A It is considered that the thickness of the minimum width region of the laminate layer D along the line is reduced. Since the pulling force when separating the under film E acts on the thinned portion intensively, the laminated layer D is broken at the thinned portion, and the laminated portion Da and the non-laminated portion Db become the recording medium. It is cut along the edge of A.

  As a matter of course, the laminate layer D of the non-laminate portion Db separated from the laminate portion Da is carried away together with the under film E.

  Further, in the separation unit 80, as shown in FIG. 9, guide surfaces (inner surfaces of the guide plates 83 and 84, which define the conveyance path across the upstream side and the downstream side of the conveyance path across the tip of the knife edge 81). Since the upper surface 81a) of the knife edge 81 is provided, even when the under film E is being separated, the laminate (A + B + E-C; A + B-C) can be stably conveyed along the conveyance path. As a result, fluttering in the normal direction of the laminate (A + B + E-C; A + B-C) can be suppressed, and the separation angle of the under film E can be stabilized. Further, when the under film E is pulled toward the under film collection unit 90, the leading portion of the recording medium A tries to follow the movement of the under film E in the initial stage, but the recording medium A is completely bent. Since the boundary between the laminated portion Da and the non-laminated portion Db is cut in a state where the posture can be restored by its own elasticity, the guide plate 84 disposed on the downstream side of the knife edge 81 is By configuring the knife edge 81 side to bend and expand the conveying path, the leading portion of the recording medium A is guided between the guide plates 83 and 84 (conveying path), and the recording medium A is on the downstream side. It is conveyed to the finished product discharge unit 150. Therefore, the finished product discharge section 150 has a clean edge along the edge of the recording medium A, and a laminate layer that is in close contact with the recording surface without air or the like being interposed between the recording medium A and the recording medium A. The recording medium A laminated in D is discharged.

<Application example>
The laminating apparatus according to the above-described embodiment performs thermocompression bonding in two stages, for example, the first time before peeling the base material C and the second time after peeling the base material C. In the second thermocompression bonding, the restraint by the substrate C is released, the laminate layer D becomes flexible, and the pressing force acts directly on the laminate layer D, so that the laminate layer D adheres to the recording surface of the recording medium A. Increases nature. Moreover, since the laminate layer D is in close contact with the recording medium A and stabilized by the first thermocompression bonding, even if the laminate layer D is directly heated and applied with a crimping force, the laminate layer D remains the same. It will not be affected. Accordingly, the surface (more precisely, the surface of the protective layer D ″) is glossy compared to the normal glossy finish lamination process (glossy recording surface (recording surface with high smoothness)) shown in FIG. The following laminating process is possible as well as the laminating process for forming the laminate layer D to have

  Application Example (Part 1): As shown in FIG. 13B, the surface becomes semi-glossy or matte with respect to a semi-glossy or matte recording surface (uneven recording surface) such as matte or silky tone. Lamination process (semi-gloss finish or matte finish laminate process) to form the laminate layer D as described above. In that case, the protective layer D ″ of the laminate layer D must have flexibility along the unevenness of the recording surface of the recording medium A by thermocompression bonding.

  Application example (Part 2): As shown in FIG. 13C, a laminate layer so that the surface is glossy with respect to a semi-glossy or matte recording surface (uneven recording surface) such as a matte tone or a silky tone. Lamination process to form D (gloss finish lamination process). In that case, the protective layer D ″ of the laminate layer D must have rigidity that does not follow the unevenness of the recording surface of the recording medium A even by thermocompression bonding.

<Second embodiment>
A laminating apparatus according to this embodiment is shown in FIG. The difference from the laminating apparatus according to the first embodiment is that first, the two crimping portions are integrated, and then the crimping roller of the crimping portion is configured to be able to contact and separate from the driving roller. is there. Others are basically the same as those in the first embodiment, and therefore, the description in the first embodiment is applied mutatis mutandis or technically, and the same reference numerals as those in the first embodiment are used. Numbering shall be done and explanation will be omitted.

  The single crimping part is used to improve the adhesion of the laminate layer D to the recording surface of the recording medium A even in one thermocompression bonding and to remove bubbles mixed between the recording medium A and the laminate layer D. This is because the effect may be acceptable at the product level.

  A roller pair contacting / separating mechanism (crimping / releasing mechanism) 46 in the crimping portion rotatably supports the roller (crimping roller 43) at the first portion and swingably supports the housing 1 at the second portion. The arm (cam follower) 460 and the first position where the pressure roller 43 is pressed against the driving roller 41 while the arm 460 is in contact with the third portion of the arm 460 and the pressure roller 43 is the driving roller 41. And a cam 461 that changes to a second position that is separated from the first position.

  The pressure bonding / release mechanism 46 is configured to separate the pressure roller 43 outward from the trajectory B ′ of the laminate B taken when the pressure roller 43 is not present. 43 does not come into contact with the laminate material B. As in the first embodiment, each of the drive roller 41 and the pressure roller 43 has a drum shape, and the pressure bonding / release mechanism 46 biases the pressure roller 43 toward the drive roller 41 at the pressure bonding position. By the urging force by the crimping / releasing mechanism 46, each is relatively elastically deformed so that the outer peripheral surfaces come into uniform contact over the entire length in the axial direction.

  Therefore, according to the laminating apparatus according to the present embodiment, for example, when laminating only one recording medium A, the pressure roller 43 is released from pressure bonding when the recording medium A passes through the pressure bonding portion 40. Then, the laminate B that is fed from the laminate supply unit 20 until the recording medium A is discharged as a finished product is laminated to the under film E that is also fed from the under film supply unit 30. Therefore, by rewinding the laminate material B and the under film E, the laminate material B can be used for the subsequent laminating process, and the laminate material B can be used effectively. is there.

  The crimping / releasing mechanism is not limited to the swinging type, and may be a direct acting type. The crimping / releasing mechanism is not limited to the system, and the first crimping of the laminating apparatus according to the first embodiment. You may apply to the part 40 and / or the 2nd crimping | compression-bonding part 50. FIG.

<Third embodiment>
A laminating apparatus according to this embodiment is shown in FIG. The difference from the laminating apparatus according to the first embodiment and the second embodiment is that the underfilm supply unit 30, the underfilm collection unit 90, and the separation unit 80 are not provided and the recording medium A is covered, Instead of adhering (transferring) the laminate layer D (laminate layer D to be the non-laminate portion Db) protruding from the periphery of the recording medium A to the under film E, the first pressure bonding according to the first embodiment or the second embodiment. It is transferred to the roller surface of the roller (roller located on the base surface side of the recording medium A: drive roller 41) corresponding to the portion 40, and the pressure bonding portion 40 causes the laminated portion Da and the non-laminated portion Db to be transferred. It exists in the point comprised so that it may function also as the isolation | separation part to divide | segment. Others are basically the same as those in the first embodiment or the second embodiment, and therefore, the description in the first embodiment or the second embodiment is applied mutatis mutandis to the first embodiment or the second embodiment. The explanation is technically read, and the same reference numerals as those of the constituent elements of the first embodiment or the second embodiment are taken together, and the explanation is omitted.

  In the pressure-bonding portion 40 according to this embodiment, the roller widths of the driving roller 41 and the pressure-bonding roller 43 are substantially the same as or wider than the width of the laminate material B, and the first embodiment or the second embodiment. As with the first press-bonding section 40, the drive roller 41 is driven to rotate so that the laminate layer D is brought into close contact with the recording surface of the recording medium A and the laminate layer D protruding from the recording medium A is driven to the drive roller 41. The laminate material B is heated and pressure-bonded to the recording medium A and the driving roller 41. As in the first embodiment, each of the drive roller 41 and the pressure roller 43 has a drum shape, and the pressure bonding / release mechanism 46 biases the pressure roller 43 toward the drive roller 41 at the pressure bonding position. By the urging by the crimping / releasing mechanism 46, each of them is relatively elastically deformed so that the outer peripheral surfaces come into uniform contact over the entire length in the axial direction. Then, the laminate material B and the recording material A, which are heat-pressed by the drive roller 41 being rotationally driven, are pressure-bonded and conveyed toward the downstream side (finished product discharge portion 150). When the recording medium A and the laminate B in the state pass through a point where the driving roller 41 and the pressure roller 43 are pressed against the recording medium A, the outer peripheral surface of the driving roller 41 and the recording medium A are downstream from the point. The drive roller 41 and the recording medium A are moved relative to each other so as to be separated from the base surface.

  In this case, as shown in FIG. 16, when the outer peripheral surface of the drive roller 41 is separated from the base surface, the laminate portion Da in which the laminate layer D is in close contact with the recording surface of the recording medium A and the periphery of the recording medium A The protruding laminate layer D is pulled at the boundary with the non-laminate portion Db in close contact with the outer peripheral surface of the drive roller 41, and similarly to the first and second embodiments, the laminate portion Da and the non-laminate portion Db are separated. The boundary is cleanly cut along the edge of the recording medium A. Therefore, the laminating apparatus according to the present embodiment causes the pressure roller 40 to function as the separating unit 80 of the first embodiment or the second embodiment by causing the driving roller 41 to function as a transfer target instead of the under film E. It is like that.

  As described above, when the driving roller 41 rotates while the extra laminating layer D (laminate layer D of the non-laminate portion Db) is attached to the outer peripheral surface of the driving roller 41, every time it reaches the point where the laminating material B is pressed. Since the laminating layer D adheres and accumulates, the laminating apparatus according to the present embodiment has the laminating layer adhering to the outer peripheral surface upstream of the point where the laminating material B is pressure-bonded to the recording medium A. A scraper (removing means) 85 whose tip is in contact with the outer peripheral surface of the drive roller 41 with a predetermined pressure is provided to scrape and remove the residue of D, and continuous lamination processing of the recording medium A is possible. It is said.

<Other embodiments>
The present invention is not limited to any of the above-described embodiments, and various modifications can be made without departing from the gist of the present invention.

  For example, in any of the above embodiments, the recording medium A recorded mainly by the ink jet recording method is the target of the laminating process, but may be a recording medium by other printing recording methods as well as the thermal transfer recording method. However, the recording medium made of a silver salt photograph is also targeted.

  In any of the above-described embodiments, the recording surface of the recording medium A is a conveying form in which the recording surface A faces upward. However, a conveying form in which the recording medium A moves in the vertical direction may be used. It may be. However, considering the provision of the pressure-bonding / releasing mechanism 46 as in the second embodiment or the third embodiment, the pressure roller is disposed on the recording surface side of the recording medium, and the driving roller is the base surface of the recording medium. It is preferable to arrange on the side.

  In any of the above embodiments, a continuous sheet is used for the laminate material B and the under film E, but a cut sheet may be used together with the recording medium A. When the laminate material B and the under film E are cut sheets, the laminate material supply unit 20 and the under film supply unit 30 are connected to the recording medium supply unit 10 regardless of whether they are supplied manually or automatically. Thus, it is necessary to change to a structure that can handle cut sheets.

  In the third embodiment, the non-laminate portion Db transferred to the roller surface is removed by the scraper 85. For example, the roller 41 is periodically removed and cleaned, or replaced with a new roller 41. You may do it.

  In any of the above embodiments, the laminate material B with the base material C is used because of good handling properties, but the base material is not essential in the present invention. In this case, the substrate recovery unit 70 is not necessary.

  In any of the above embodiments, a long laminate material B having a width wider than that of the recording medium A is used so that the laminate material B protrudes from the length and width of the recording medium A. For example, the recording medium A A long laminate B having the same width as the width (the length in the direction orthogonal to the conveyance direction of the recording medium A (the direction in which the laminate material B is pulled out)) may be used. In this case, the recording medium A is sequentially supplied so that there is a gap between the preceding recording medium A and the succeeding recording medium A, and the recording medium A and the laminate material B (continuous sheet) on the conveyance path. If the under film E is conveyed while being guided by the width regulation guide, the entire recording surface of the recording medium A can be covered with the laminate material B and laminated, and the consumption of the laminate material is reduced. can do. Even in this case, by separating the under film E from the recording medium A, the laminated portion Da and the non-laminated portion Db are formed at the leading and trailing ends of the recording medium A in the traveling direction as in the above embodiment. It will be cut off at the edge.

  In any of the above embodiments, a long laminate material B wider than the recording medium A is used, and an interval is provided between the preceding recording medium A and the succeeding recording medium A. The recording medium A is sequentially supplied so that the laminating material B (laminate layer D) protrudes from the vertical and horizontal (periphery) of the recording medium A. For example, a long laminating material that is wider than the recording medium A B may be used to sequentially supply the recording medium A so that the preceding recording medium A and the succeeding recording medium A are in close contact with each other. Even in this case, the entire surface of the recording surface of the recording medium A can be covered with the laminate material B, and wasteful consumption of the laminate material B can be suppressed. Also in this case, by separating the under film E from the recording medium A, the laminate portion Da and the non-laminate portion Db are bordered on the edge extending in the traveling direction of the recording medium A as in the above embodiment. Can be separated. However, since the laminate layer D and the under film E are not pressure-bonded between the preceding recording medium A and the succeeding recording medium A, the preceding recording medium A and the succeeding recording medium A are laminated layers. Although the recording medium A is in a connected state via D, by separating the recording media A relatively, the laminate layer D that connects the recording media A may be broken to divide the recording media A. it can.

  In any of the above embodiments, the drive roller 41 (51) and the pressure roller 43 (53) are formed in a drum shape, and each is relatively elastically deformed by the biasing force acting on the pressure roller 43 (53). The outer peripheral surface of the pressure roller 43 (53) is configured to be in uniform contact with the outer peripheral surface of the drive roller 41 (51). However, the present invention is not limited to this. For example, the drive roller 43 (53) is substantially omitted. It is configured by a true cylindrical roller so as not to be elastically deformed even when the pressure adjusting mechanism 45 (movable body 452) or the pressing / releasing mechanism 46 is actuated. And may be configured to be elastically deformed by urging by the pressure adjusting mechanism 45 (movable body 452) or the pressure bonding / release mechanism 46. In this way, the pressure roller 43 (53) is brought into pressure contact with the drive roller 41 (51) by the urging force of the pressure adjusting mechanism 45 (movable body 452) or the pressure bonding / release mechanism 46 as in the above embodiment. As a result, the pressure roller 43 (53) is elastically deformed, and the pressure roller 43 (53) can be brought into contact with the outer peripheral surface of the drive roller 41 (51) in a linear or belt-like region. The recording medium A and the under film E can be uniformly pressed (heat-pressed).

  In any of the above-described embodiments, the shaft body and the outer peripheral surface of the pressure roller 43 (53) are elastically deformed, so that the outer peripheral surfaces of the drive roller 41 (51) and the pressure roller 43 (53) are in uniform contact with each other. However, the present invention is not limited to this. For example, when a biasing force is applied to the pressure roller 43 (53), only the shaft body of the pressure roller 43 (53) is bent (elastically deformed). And the laminating material B can be pressed by a linear or belt-like region extending in the axial direction of the outer peripheral surface of the pressure roller 43 (53) by bending of the pressure roller 43 (53). . Further, the rigidity of the shaft body of the pressure roller 43 (53) is increased so that the shaft body of the pressure roller 43 (53) does not elastically deform even when an urging force is applied, and the pressure roller when the urging force is applied. Of course, only the outer peripheral surface of 43 (53) may be elastically deformed. Even in this case, the laminate material B can be pressed in a linear or belt-like region extending in the axial direction of the outer peripheral surface of the pressure roller 43 (53), and the laminate material B is uniformly applied to the recording medium A. Can be thermocompression bonded.

  In any of the above-described embodiments, the driving roller 41 (51) that rotationally drives the roller that receives the biasing force acting on the pressure roller 43 (53) is used, but the present invention is not limited to this, and the pressure roller 43 (53) is not limited thereto. ) May be rotationally driven, or the driving roller 41 (51) and the pressure roller 43 (53) may be rotationally driven in synchronization.

  In any of the above-described embodiments, the laminate material B is larger than the recording medium A, and the laminate layer D is transferred onto the outer film E or the outer peripheral surface of the drive roller 41, so that the edge is covered. The laminate layer D along the edge of the recording medium A is formed on the recording surface. However, the present invention is not limited to this, and the size of the laminate material B is made to correspond to the size of the recording medium A, and is pressed. Of course, the laminate layer D may be transferred only to the recording surface of the recording medium A by the portion (the first pressure bonding portion 40 or the like).

  Moreover, although said 1st embodiment and 2nd embodiment have arrange | positioned the separation part 80 of the underfilm E to the downstream rather than the peeling part 60 of the base material C, the separation part 80 is the same as 3rd embodiment. (= Crimping part 40) is disposed upstream of the peeling part 60, and the laminated part Da and the non-laminated part Db are separated while the base material C is still attached, and then the base material C is laminated to the laminated part. You may make it peel from the laminate layer D which became only Da.

  In the first embodiment and the second embodiment, the laminating material B, the recording medium A, and the under film E are heated and pressure-bonded by the driving roller 41 and the pressure roller 43. However, the present invention is not limited to this. Instead, for example, instead of the drive roller 41, a flat guide plate that slides the under film E in a laminated state may be provided. Even in this case, the biasing force of the pressure roller 43 is received by the guide plate, and the pressure roller 43 whose both ends are biased toward the conveyance path bends along the guide surface of the guide plate (elastic deformation). Will be). Thereby, similarly to the first embodiment and the second embodiment, the laminate material B can be uniformly pressed against the recording medium A and the under film E. If the guide plate is provided in place of the drive roller 41 in this way, it becomes difficult to smoothly convey the laminate only by the rotation of the pressure roller 43. For example, in the base material recovery unit 70 or the under film recovery unit 90 What is necessary is just to make it convey a laminated body to the downstream side using winding up the base material C or the underfilm E (drawing). However, in order to smoothly convey the laminated body, as in the laminating apparatus of the first embodiment and the second embodiment, the crimping portions 40 and 50 are configured by a pair of rollers, and the laminate material B and the recording medium A are recorded. And it is preferable that the laminated body made of the under film E is configured so that it can be sent to the downstream side while being hot-pressed.

  In the third embodiment, the non-laminate portion Db is transferred to the roller surface of the roller 41. However, for example, the non-laminate portion Db may be transferred to the belt surface of an endlessly rotating belt.

  In any of the above-described embodiments, the laminate film Da and the non-laminate film Db are automatically separated by pulling out the under film E from the conveyance path via the separating unit 81 or by using a rotating roller surface as a transfer target. For example, as a reference example, at least the first pressure bonding without providing the base material collection unit 70, the under film collection unit 90, the separation unit 80, etc. in the first embodiment and the second embodiment. The recording medium A, the laminate material B, and the under film E are pressure-bonded at the section 40, and the recording medium A is sandwiched between the laminate material B and the under film E (the recording medium A is in a sandwich state). You may make it discharge | emit as a laminated body. In addition, a cutting device that cuts between the recording medium A in the laminate of the recording medium A, the laminate material B, and the under film E without providing the base material recovery unit 70, the under film recovery unit 90, the separation unit 80, and the like. It may be provided on the downstream side of the first pressure-bonding part 40 or the second pressure-bonding part 50, and the laminated body of the recording medium A, the laminate material B, and the under film E may be discharged in a single wafer state. In this way, as shown in FIG. 17, when the operator manually peels the under film E from the laminate material B (turns the under film E), the same action as in the above embodiment occurs, and the laminate portion Da and the non-laminate portion Db can be separated.

The perspective view of the laminating apparatus concerning a first embodiment is shown. The side view of the lamination apparatus which concerns on the same embodiment is shown. The perspective view containing the partial cross section of the laminating apparatus which concerns on the same embodiment is shown. The side view containing the partial cross section of the laminating apparatus which concerns on the same embodiment is shown. The principal part enlarged side view in the vicinity of the 1st crimping | compression-bonding part of the laminating apparatus which concerns on the embodiment is shown. The front view of the press roller of the laminating apparatus which concerns on the same embodiment is shown. The drive roller and pressure roller of the laminating apparatus which concern on the embodiment are the states crimped | bonded, Comprising: The front view of the state which the drive roller and the pressure roller bent is shown. The principal part enlarged side view in the 2nd crimping | compression-bonding part and peeling part vicinity of the lamination apparatus which concerns on the embodiment is shown. The principal part expanded side view in the 2nd crimping | compression-bonding part and isolation | separation part vicinity of the lamination apparatus which concerns on the embodiment is shown. Sectional drawing of the laminating material used for the laminating apparatus which concerns on the embodiment is shown. In the laminating apparatus according to the embodiment, (a) is a plan view of a laminate in which a laminate material is laminated, and (b) is a cross-sectional view taken along the line II of (a). The state figure when an under film is isolate | separated from a recording medium in the isolation | separation part of the lamination apparatus which concerns on the embodiment is shown. FIG. 2 is a cross-sectional view of a finished product obtained by the laminating apparatus according to the embodiment, in which (a) is based on a normal gloss finish lamination process, and (b) is a half using a semi-glossy recording medium. Glossy finish lamination process (c) is a glossy laminate process using a semi-glossy recording medium. The side view of the lamination apparatus which concerns on 2nd embodiment is shown. The side view of the lamination apparatus which concerns on 3rd embodiment is shown. The state figure at the time of a recording medium passing the crimping | compression-bonding part of the lamination apparatus which concerns on the embodiment is shown. The state figure at the time of peeling the under film of the laminated body processed with the laminating apparatus which concerns on a reference example from a laminate material manually is shown. The schematic side view of the conventional laminating apparatus is shown.

Explanation of symbols

1 Housing 10 Recording medium supply unit (supply unit)
11 Mounting plate 100 Conveying roller pair 150 Finished product discharge unit (discharge unit)
151 Mounting plate 20 Laminate supply unit (supply unit)
21 Holder (Laminate material holder)
30 Under film supply section (supply section)
31 Holder (Under film holder)
40 First crimping part (crimping part)
41 Drive roller 43 Pressure roller 45 Pressure adjustment mechanism 46 Pressure release mechanism 50 Second pressure bonding part (pressure bonding part)
51 Driving roller (roller)
53 Pressure roller 55 Pressure adjusting mechanism 60 Peeling part 61 Knife edge (peeling guide body)
70 Substrate collection unit (collection unit)
71 Holder (collected substrate holder)
80 Separation part 81 Knife edge (separation guide body)
85 Scraper (removal means)
90 Under film collection unit (collection unit)
91 Holder (Recovery under film holder)
A Recording medium B Laminating material C Base material D Laminating layer Da Laminating part Db Non-laminating part D 'Adhesive layer D''Protective layer E Under film (material to be transferred)

Claims (4)

The pressure roller is supported at both ends and urged in a direction substantially perpendicular to the axis, and the pressure roller heats the laminate material superimposed on the recording surface of the sheet-like recording medium. On the other hand, in the laminating apparatus configured to press and apply the pressing force to the laminate material and the recording surface, the laminate material is transferred to the recording surface in a wider area than the planar area of the recording medium. The pressure roller is formed in a drum shape with the outer diameter decreasing from the substantially central portion in the axial direction toward both ends, and elastically deformed by the biasing force. is configured, and, between the object transfer means for transferring the laminate and the laminate layer, in a state where the recording surface is interposed a recording medium so as to face the laminated layer, the laminate The recording medium is configured such that the laminate layer is in close contact so that the surface to be transferred and the surface opposite to the recording surface of the recording medium are separated from each other. A laminating apparatus configured to relatively move a medium and a transfer target unit.   Both ends are pivotally supported so that the shaft center is substantially parallel to the shaft center of the pressure roller, and the roller is configured to receive the urging force by the pressure roller via the laminate material and the recording medium. The drum is reduced in size from the substantially central portion in the axial direction toward both ends, and is configured to be elastically deformed by receiving the urging force. At least one of the roller and the pressure roller rotates. The laminating apparatus according to claim 1, wherein the laminating apparatus is configured to be driven. An under film supply unit that supplies an under film serving as the transfer means wider than the planar area of the recording medium between the roller and the pressure roller is further provided, and the laminate material and the under film are disposed so that the laminate layer faces the recording surface. 3. A laminating apparatus according to claim 2, wherein the recording medium is interposed between the recording medium and the under film, and the laminating material is heated and pressure-bonded to the recording medium and the under film by a roller and a pressure roller. 3. The laminating apparatus according to claim 2, wherein the roller that receives the urging force from the pressure roller via the laminating material and the recording medium constitutes a transfer-receiving means to which the laminate layer protruding from the recording medium is transferred.

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