JP2005111985A - Image forming method and image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming method and an image forming apparatus capable of providing different degrees of gloss in different areas of the image depending on the various contents e.g. objects or patterns, so as to form a high-quality image that properly expresses texture. <P>SOLUTION: The image forming method includes a recording step of recording an image according to image data, a material setting step of setting a coating film to be provided on an image recording layer according to glossiness data indicating glossiness of the image reproduced by the image data, a condition setting step of setting a condition of a surface processing of the coating film by considering the set coating film and according to the glossiness data, and a processing step of performing the surface processing of the coating film in accordance with the determined surface processing condition. The image forming apparatus is also disclosed. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention belongs to the technical field of image formation, and particularly relates to an image forming method and an image forming apparatus capable of forming a high-quality image with appropriate gloss depending on a pattern or the like.

  In order to improve the added value of images (hard copy) output by inkjet printers and electrophotographic printers, the surface should be glossy like photo prints, and the surface gloss level should be moderated so that images can be viewed appropriately. Various surface treatment techniques are known for controlling the surface.

  For example, in Patent Document 1, after forming a color image in electrophotographic image formation, a transparent layer made of inorganic oxide fine particles having a refractive index of 1.4 to 1.6 and a water-soluble resin is formed, and Disclosed is a method for forming a color image having a uniform glossiness such as a photographic print by making a predetermined relationship between the refractive index of the toner that formed the image, the refractive index of the inorganic oxide fine particles, and the thickness of the transparent layer. Has been.

  Patent Document 2 discloses a silicone oil whose temperature is controlled so that the viscosity is 0.1 P or more and the surface tension is 15 dyn / cm or less on the surface of a fixed toner layer in the same electrophotographic image formation. A method of forming an image with sufficient glossiness, such as a photographic print, while preventing the offset by adhering is disclosed.

  Further, Patent Document 3 also uses a rough surface roller whose surface is roughened as a roller that comes into contact with the image forming surface after an image is formed in electrophotographic image recording, and according to the selected glossiness. Thus, an image forming apparatus capable of forming an easy-to-see image with low glossiness by adjusting the contact force of the rough roller in consideration of the material (transfer material) on which the image is formed is disclosed.

Japanese Patent Laid-Open No. 10-319621 JP 2001-92171 A Japanese Patent Laid-Open No. 2000-244841

  According to the methods disclosed in each of these patent documents, the surface of the image is given gloss like a photographic print, or the glossiness of the image surface is reduced to improve the observability. Added value can be improved.

Here, the image formed by such a printer has various patterns, and in order to obtain a higher added value image, a suitable glossiness can be imparted with a high degree of freedom in accordance with the pattern or the like. Is preferred.
In addition, in an image, there is an object having gloss (an image constituent), and there is an object having no gloss at all. Therefore, in order to form a higher quality image with improved image quality, it is preferable to give different glossiness for each region depending on the pattern.
However, in the methods disclosed in these patent documents, the degree of freedom in selecting glossiness is low, and it is often impossible to impart suitable glossiness according to the image. In addition, the methods disclosed in these patent documents can provide only uniform glossiness over the entire surface of the image, and cannot provide glossiness according to the pattern, which differs in the area within the image. Further, when controlling the gloss of the image surface according to the pattern, it is necessary to perform processing under conditions according to the target gloss in order to obtain a desired gloss corresponding to various recording media. However, the conventional technique cannot perform such gloss control.

  An object of the present invention is to solve the problems of the prior art, and can provide suitable glossiness with a high degree of freedom, depending on the pattern of the image, such as an object present in the image, and more preferably. An object of the present invention is to provide an image forming method and an image forming apparatus capable of forming an appropriate glossiness corresponding to a different pattern for each region, and thereby forming a high-quality image expressing the texture well.

  In order to achieve the above object, the present invention provides a recording process for recording an image on an image recording layer of an image recording medium according to image data, and glossiness data indicating the glossiness of a reproduced image of the image data. A material setting step for setting a coating film disposed on the image recording layer, and a condition setting step for setting surface treatment conditions for the coating film according to the set coating film and the gloss data And an image forming method characterized by comprising a processing step of performing a surface treatment of the coating film according to the determined surface treatment conditions.

  In such an image forming method of the present invention, the glossiness data preferably indicates the glossiness in each region of the reproduced image, and the material setting step includes the glossiness data and the coat film. It is preferable that the coating film is set using a table having parameters as.

  The surface treatment in the treatment step uses a heating means for heating the surface of the coating film and a pressing means for pressing a pressing member against the surface of the coating film, and the condition setting step includes the glossiness data And a table having at least one of a heating temperature by the heating means, a heat treatment time, a pressing force by the pressing means, a surface roughness of the pressing member, and a pressing time by the pressing means in addition to the coating film. It is preferable to set the surface treatment conditions, and the heating means preferably performs local control to heat the surface of the coat film, and further, the image recording is performed. The resolution is preferably an integer multiple of the resolution of the surface treatment.

  In order to achieve the above object, the present invention includes a medium supply unit that supplies an image recording medium, an image recording unit that records an image on an image recording layer of the image recording medium according to image data, and the image A coat film disposed on the image recording layer is set according to glossiness data indicating the glossiness of a reproduced image of the data, and the coat is set according to the set coat film and the glossiness data. A control unit for setting surface treatment conditions of the film, a coat film stacking unit for stacking the coat film set by the control unit on the surface on which the image of the image recording medium is recorded, and the control unit An image forming apparatus comprising: a surface treatment unit that performs surface treatment of the coat film according to surface treatment conditions of the coat film.

  In such an image forming apparatus of the present invention, it is preferable that the gloss data indicates the gloss in each area of the reproduced image, and the control unit uses the gloss data and the coat film as parameters. It is preferable to set the coat film using a table.

  The surface treatment unit includes a heating unit that heats the surface of the coating film and a pressing unit that presses a pressing member on the surface of the coating film, and the control unit applies the gloss data and the coating film to the surface. In addition, by using a table having at least one of a heating temperature by the heating unit, a heat treatment time, a pressing force by the pressing unit, a surface roughness of the pressing member, and a pressing time by the pressing unit as parameters, It is preferable to set processing conditions.

  The heating means preferably performs local control to heat the surface of the coating film, and the resolution of image recording by the image recording unit is the resolution of the surface treatment by the surface processing unit. It is preferable that it is an integral multiple of.

  According to such an image forming method and an image forming apparatus of the present invention, glossiness can be given with a high degree of freedom according to the design for each region of the image, such as an object present in the image, and is more preferable. Depending on the pattern, different glossiness can be imparted at each position in the image, whereby a high-quality image (hard copy) that suitably expresses the texture can be formed.

  Hereinafter, an image forming method and an image forming apparatus of the present invention will be described in detail based on preferred embodiments shown in the accompanying drawings.

FIG. 1 is a conceptual diagram of an example of an image forming apparatus of the present invention that implements an example of an image forming method of the present invention.
An image forming apparatus 10 shown in FIG. 1 records an image on the surface (image recording layer) of an image recording medium 12 (hereinafter referred to as a recording medium 12) by inkjet, and then laminates a coat film 14 on the image recording surface. Next, the coating film 14 is subjected to surface treatment. Basically, the medium supply unit 16, the cutter 18, the image recording unit 20, the coating film stacking unit 22, the surface processing unit 24, and the control unit 26. It is comprised. Although not shown in FIG. 1, the image forming apparatus 10 also forms an image using a sheet-like material such as a conveying unit, a conveying guide, a positioning unit, and various sensors for the recording medium 12 and the coating film 14. You may have various components which the apparatus and the apparatus in which the lamination process of a sheet-like material exists have.

The medium supply unit 16 (hereinafter referred to as the supply unit 16) is a part that supplies the recording medium 12 on which an image is recorded (drawn).
In the illustrated example, the recording medium 12 is loaded in the supply unit 16 as a medium roll 28 wound in a long state, and the supply roller pair 30 pulls out the recording medium 12 from the medium roll 28 and conveys it downstream. To do.

  As shown by dotted lines in the figure, a plurality of medium rolls 28 are prepared by winding different recording media 12. The supply unit 16 supplies the designated recording medium 12 from the corresponding medium roll 28 in accordance with, for example, an input instruction from the operator. Note that the number of the recording medium 12 may be one or any number of two or more. Further, in the image forming apparatus 10, the number of media rolls 28 that can be loaded into the supply unit 16 may be one, and an operator or the like may be appropriately replaced according to an image (hard copy) to be formed. Good.

In the present invention, the recording medium 12 that can be used is not particularly limited. For example, plain paper or inkjet paper is used when inkjet is used, and plain paper or a photo printer is used when electrophotography is used. In some cases, a photographic paper or other support and an image recording layer (a color material layer (including a holding (impregnation) region of ink or toner on the support)) and an image in an image recording unit 20 described later are provided. Various recording media can be used as long as they correspond to the recording method.
Further, the thickness of the recording medium 12 is not particularly limited, and may be in a normal range corresponding to the recording medium 12, but is preferably 50 to 150 μm.

The recording medium 12 supplied from the supply unit 16 is conveyed to the image recording unit 20 by the supply roller pair 30 and the scanning conveyance roller pair 32 of the image recording unit 20. A cutter 18 is disposed between the supply roller pair 30 and the scanning conveyance roller pair 32.
The cutter 18 is a known sheet cutting means. The conveyance of the recording medium 12 by the supply roller pair 30 and the scanning conveyance roller pair 32 is temporarily stopped when the length of the recording medium 12 reaching the downstream of the cutter 18 reaches the size of the formed image (hard copy). . Next, the cutter 18 is actuated to cut the recording medium 12 to form a cut sheet of the formed image size. Thereafter, the scanning conveyance roller pair 32 resumes conveyance and conveys it to the downstream recording position.

The image recording unit 20 (hereinafter referred to as the recording unit 20) is a known image recording unit that performs inkjet image recording on the surface (image recording layer) of the recording medium 12, and includes a pair of scanning conveyance rollers 32 and 34, and And an ink jet recording head 36 (hereinafter referred to as a recording head 36) disposed between the two.
The recording head 36 is a known inkjet recording head, and may be, for example, a thermal inkjet recording head, a piezo type inkjet recording head, or an electrostatic type inkjet recording head.

The recording head 36 has a so-called line having a nozzle (ink ejection hole) row having a length exceeding the maximum size in the width direction of the corresponding recording medium 12 (the direction perpendicular to the longitudinal direction before cutting is hereinafter referred to as the width direction). Head. The recording head 36 has, for example, four nozzle rows that eject ink droplets of C (cyan), M (magenta), Y (yellow), and K (black), and the nozzle rows extend. The direction is aligned with the width direction, and the ink discharge direction is arranged at a predetermined recording position.
In the recording unit 20, while the recording medium 12 is scanned and conveyed in the direction orthogonal to the width direction by the scanning conveyance roller pairs 32 and 34, droplets are discharged from each nozzle in accordance with image data supplied from the control unit 26 described later. By modulating and driving the droplet discharge means for discharging the ink droplets, the ink droplets of the recording head 36 are discharged, thereby recording four full-color images corresponding to the image data on the surface of the recording medium 12.

  In the present invention, image recording by inkjet is not limited to that using a line head, and the direction in which the conveyance direction of the recording medium 12 coincides with the nozzle row direction and is orthogonal to the conveyance direction (in the illustrated example). If so, inkjet image recording using a so-called serial head that scans (shuttles) the recording head in the width direction of the recording medium 12 and intermittently conveys the recording medium 12 according to the scanning of the recording head. Also good.

  In the present invention, the recording of the image on the recording medium 12 is not limited to inkjet, and may use electrophotography, or photographic paper (with a light beam modulated in accordance with the recorded image ( A digital photographic printer that scans and exposes a photosensitive material) and then performs predetermined wet development processing and drying may be used. Alternatively, the photosensitive material (with a light beam modulated according to a recorded image) may be used. The latent image may be recorded by exposing a donor), and the image may be thermally developed and transferred to an image receiving medium in the presence of an image forming solvent, and various image recording methods can be used.

Next, the recording medium 12 on which the image has been recorded is conveyed to a coating film stacking section 22 (hereinafter referred to as a stacking section 22) having a stacking unit 38 and stacked with the coating film 14.
The laminating means 38 is a known sheet-like material laminating / sticking means having an alignment means, a pressing roll, and the like, and further includes a drawing means for the coating film 14, a conveying means, a cutter, and the like.

In the illustrated example, as with the recording medium 12, the coat film 14 is also wound in a long state and loaded as a coat film roll 39 into the stacked unit 22.
The laminating means 38 draws the coat film 14 from the coat film roll 39 by a pair of draw rollers, cuts it to the same size as the recording medium by a cutter, aligns the two (applying an adhesive or the like if necessary) ) Laminated and pressure-bonded (heated if necessary) to form a laminate in which the coating film 14 is laminated on the surface of the recording medium 12.

As indicated by dotted lines in the figure, like the medium roll 28 described above, a plurality of coat film rolls 39 each having a different coat film 14 wound thereon are loaded. The stacking unit 22 supplies the specified coat film from the corresponding coat film roll 39 in accordance with an instruction from the control unit 26 to be described later, and stacks it on the recording medium 12.
Each coating film 14 is different in forming material, thickness, surface roughness, and the like. As described later, if any one of these elements is different, the gloss level that can be expressed is different. Therefore, in the present invention, even with the same material, the coat film 14 having a different thickness, the coat film 14 having a different surface roughness, and the coat film 14 having a different refractive index are handled as different types of coat films 14. Further, the number of the coating film 14 may be one, but is preferably an arbitrary number of 2 or more. Further, the number of coat film rolls 39 that can be loaded into the laminated section 22 may be one, and an operator or the like may be appropriately replaced.

In the present invention, the coat film 14 that can be used is not particularly limited, and various types can be used as long as they do not hinder the observation of the image recorded on the recording medium 12.
Examples include polyurethane resins disclosed in JP-A-10-34909, silicone resins disclosed in JP-A-10-309984, polyethylene-based thermoplastic resins disclosed in JP-A-2000-108454, and the like. Illustrated.
Also, the thickness is not particularly limited, and may be appropriately determined according to the material to be used, but is usually preferably 10 to 100 μm.

  As will be described later, in the image forming method of the present invention, the heating unit (glaze surface) is locally heated by the thermal head 46 having a certain surface roughness to perform surface treatment of the coat film 14. By doing so, the surface roughness of the heating part of the thermal head 46 is transferred, the surface roughness of the coating film 14 is adjusted for each area of the image, and the image to be formed, such as an object constituting the image, is in accordance with the pattern. Glossiness is given and the texture is suitably expressed.

In the image forming apparatus 10 in the illustrated example, the coat film 14 is formed on the recording medium 12 by using the sheet-like coating film 14 and laminating the image recording surface of the recording medium 12. However, the present invention is not limited to this. For example, a coating film that forms a coating film on the recording medium 12 may be applied according to the target thickness and dried to form the coating film on the recording medium 12. Good. Alternatively, the coating film may be formed by ejecting a transparent coating liquid using an inkjet or the like.
Furthermore, if necessary, a surface roughening treatment may be performed on the coat film formed using the paint in this manner prior to the surface treatment.

The laminate 40 of the recording medium 12 and the coating film 14 laminated in the lamination unit 22 is then conveyed to the surface treatment unit 24 by the conveyance roller pair 42, and the coating film 14 is subjected to surface treatment, and the image of the present invention. An image (hard copy) is formed by the forming method, and is conveyed by a discharge roller pair 44 to a discharge tray or the like (not shown).
The surface treatment unit 24 includes a thermal head 46 and a platen roller 48.

The thermal head 46 is a known thermal head having a heating portion (glaze) in which heating elements (heaters) each including an electrode and a heating resistor are arranged in one direction. The arrangement direction of the heating elements is determined by a platen roller 48. Arranged so as to be orthogonal to the transport direction (that is, the width direction and the extending direction of the element rows coincide).
Here, in the present invention, the thermal head 46 (surface treatment means) for performing the surface treatment does not require a very high resolution, and for example, it may be a resolution of about 50 dpi that is visually uncomfortable and reduces the cost. it can. Further, by making the resolution of the recording head 36 (recording means) an integer multiple of the resolution of the thermal head 46, the control of the surface treatment can be simplified.

In the surface processing unit 24, the platen roller 46 is rotated in a state where the laminated body 40 is sandwiched between the thermal head 46 (the heating / pressing unit) and the platen roller 48 in the same manner as image recording by a known thermal recording printer. Thus, the stacked body 40 is nipped and conveyed in the longitudinal direction (direction orthogonal to the width direction). In parallel with this nipping and conveying, each heating element of the thermal head 46 is modulated and driven according to the surface treatment condition (heating temperature) supplied from the control unit 26.
At this time, by using the thermal head 46 having a certain surface roughness (surface property) in the heating part (pressing part), the surface roughness of the heating part of the thermal head 46 is changed to the surface of the coat film 14 by heating / pressing. Can be transferred to. Here, when the heating temperature is low, the surface roughness of the heating portion of the thermal head 46 is not sufficiently transferred, and is transferred to the surface of the coating film 14 in a slack state (that is, with respect to the surface roughness of the heating portion). Thus, a small surface roughness is transferred to the surface of the coating film 14).
Therefore, by locally controlling the heating by the thermal head 46, the surface of the coat film 14 is heated / pressurized under different heating conditions in each region, and the target surface roughness is applied to the surface of the coat film 14. Can be formed (transferred). In the image forming apparatus 10 of the illustrated example, the surface roughness of each area of the image is determined according to glossiness data described later, and an object existing in the image (recorded image in the recording unit 20) is present in each area of the image. Glossiness according to the pattern is given.

  In the present invention, as indicated by dotted lines in the drawing, a plurality of thermal heads 46 having different surface roughnesses of the heating portion are prepared, and the thermal head to be used is used according to the target surface roughness of the coating film 14. The head 46 may be selected. At this time, the thermal head 46 is selected by the control unit 26 according to the relationship between the coating film and the surface roughness, which will be described later, or the like that can achieve the target surface roughness range. That's fine.

  In the present embodiment, the thermal head 46 that combines the heating unit and the pressing unit is used, but the heating unit and the pressing unit may be provided separately. In that case, first, the coating film 14 may be heated by the heating means, and then the pressing member may be pressed against the surface of the coating film 14 by the pressing means.

The control unit 26 controls the entire image forming apparatus 10, and sets (selects) the coating film 14 using a material setting table to be described later according to the supplied image data and glossiness data. An instruction is given to the supply unit 16 and the stacking unit 22.
Further, the image data is supplied to the recording head 36. Furthermore, surface processing conditions such as driving conditions for the thermal head 46 are set using a processing condition table to be described later and supplied to the thermal head 46 and the like.

In the present invention, the image data is known two-dimensional image data corresponding to the image recording to be performed. Therefore, in the illustrated example, C, M, Y, and K images corresponding to image recording by the recording head 36 are shown. It is data.
On the other hand, the glossiness data is two-dimensional glossiness data corresponding to each area in an image obtained by reproducing the image data supplied to the control unit 26 together with the glossiness data. For example, if the recorded image (reproduced image of the image data) is an image having the table 60 as shown in FIG. 2, the area of the table 60 has a glossiness of 25% and the other background areas have a glossiness of 10%. It is such data. Further, in FIG. 2, if the image is such that a (CD) case is placed on the table 60 and a CD is placed thereon, the area of the table 60 has a glossiness of 25% and the case area is The data is such that the glossiness is 30%, the CD area is 40% glossiness, and the other background areas are 10% glossiness.

In the present invention, the glossiness data is not limited to the data that directly indicates the glossiness of each area as described above.
For example, the glossiness of metal is 40%, the luster of wood is 25%, the gloss of fabric is 10%, and the gloss of paper is 15%. The control unit 26 may be set so that the material of the region is supplied as glossiness data, and the control unit 26 may know the glossiness of each region accordingly.

  In the present invention, the glossiness is measured or glossed in a state including light absorption by the coating film 14 and reflection by the recording medium 12 in accordance with, for example, the method of measuring the specular glossiness of JIS Z8741. The degree data may be determined.

  Hereinafter, the operation of the image forming apparatus 10 will be described to describe the image forming method of the present invention in more detail.

In a hard copy consisting of an image recording medium 12 (support / image recording layer) / coat film 14 created by the image forming apparatus 10 in the illustrated example, as shown schematically in FIG. The (reflected light I _{out with} respect to the incident light I _in ) is mainly determined by the refractive index n of the coat film 14, the film thickness d of the coat film 14, and the surface roughness Ra of the coat film 14. Strictly speaking, the refractive index and film thickness of the surface of the image recording medium 12 (image recording layer) also affect the surface gloss, but are often negligible visually.
In the present invention, as shown in FIG. 4, first, in each region of the image, in order to express a desired glossiness according to the pattern such as the table 60 or the background, the coating film 14 (material, thickness, (Surface roughness, etc.) is set (material setting step; step S1), and further, surface treatment conditions for setting the surface of the coating film 14 to the desired surface roughness are set (condition setting step; step S2). A surface treatment is performed on the film 14 (processing step; step S3).

As described above, when the image data of the recorded image and the corresponding glossiness data are supplied to the control unit 26, the control unit 26 supplies the image data to the recording unit 20 and uses the glossiness data. The coating film 14 to be used is set.
In the control unit 26, a material setting table showing the relationship between the surface roughness Ra [μm] and the glossiness [%] as shown in FIG. When the glossiness data is supplied, the control unit 26 knows the glossiness range to be expressed in this image (hard copy), and uses the material setting table to obtain the target glossiness from the plurality of types of coat films 14. The coating film 14 capable of expressing the degree is selected.

For example, as shown in FIG. 5A, assuming that two coating films 14 (thicknesses 50 μm and 100 μm) having the same formation material and surface roughness and different thicknesses are prepared, the image shown in FIG. When the glossiness data is supplied such that the area of the table 60 has a glossiness of 25% and the background area has a glossiness of 10%, the control unit 26 refers to the material setting table and sets both glossiness values. A coat film 14 having a film thickness of 100 μm that can be expressed is selected, and an instruction is given to the laminated section 22 to use this coat film 14.
Note that, for example, when there are a plurality of coat films 14 whose conditions are required in the surface treatment condition setting step described later according to the target glossiness, that is, when a plurality of coat films 14 are available, What is necessary is just to select suitably.

Next, the control unit 26 sets the surface roughness Ra for expressing the target glossiness for each area of the image from the glossiness data using the material setting table for the selected coat film 14.
That is, in the example shown in FIG. 2, the glossiness data is supplied with the table 60 area having a glossiness of 25% and the other background areas having a glossiness of 10%. Correspondingly, using the material setting table of FIG. 5 (A), the surface roughness Ra of the table region having a glossiness of 25% is 7 μm, and the surface roughness Ra of the background region having a glossiness of 10% is 20 μm. Set.

Further, the control unit 26 sets surface treatment conditions by the thermal head 46 for realizing the surface roughness of the coating film 14 for each region in accordance with the glossiness data, that is, the set surface roughness Ra.
For each coat film 14, the control unit 26, as shown in FIG. 5B, the surface roughness Ra of the coat film 14 and the heating temperature T [° C. of surface treatment by the thermal head 46 for realizing this. ] Has a condition setting table showing the relationship with In the illustrated example, assuming that the thermal head 46 having a surface roughness of 40 μm is used, the region having a surface roughness Ra of 20 μm (glossiness 10%) using this condition setting table is a heating temperature for realizing this. In the region where 80 ° C. is set and the surface roughness Ra is 7 μm (glossiness 25%), the heating temperature 52 ° C. for realizing this is set.
Next, the control unit 46 supplies information on the heating temperature set for each image region to the surface processing unit 24.

Thus, when the coating film 14 to be used and the surface treatment condition (heating temperature) by the thermal head 46 are determined and supplied to each part, first, the supply roller pair 30 of the supply unit 16 is selected (designated). The recording medium 12 is pulled out from the medium roll 28 corresponding to the recording medium 12 and supplied to the cutter 18, and the cutter 18 cuts the recording medium 12 according to the formed image size as described above.
Next, in the recording unit 20, a full color image is recorded on the surface of the recording medium 12 according to the image data supplied by the recording head 36 while the scanning conveyance roller pairs 32 and 34 scan and convey the recording medium 12. .

Next, in the laminating portion 22, the laminating means 38 pulls out the coat film 14 from the coat film roll 39 corresponding to the selected coat film 14, cuts according to the formed image size, and the surface of the recording medium 12 on which the image is recorded. Laminate / stick.
Next, the conveying roller pair 42 conveys the laminated body 40 of the recording medium 12 and the coating film 14 to the surface treatment unit 24, and is nipped and conveyed by the thermal head 46 (heating unit) and the platen roller 48, while the surface treatment unit 24. Then, the thermal head 46 (each heating element) is driven according to the supplied heating temperature (surface treatment conditions) to perform the surface treatment of the coat film 14 (step S3 in FIG. 4). Thereby, the surface roughness of the heating part of the thermal head 46 is transferred to the surface of the coating film 14 according to the heating temperature, and the surface of the coating film 14 is made to have a surface roughness corresponding to the target glossiness.

  In this way, the laminate 40 (that is, the image (hard copy) formed by the image forming method of the present invention) on which the coating film 14 has been subjected to the surface treatment has the discharge roller pair 44 placed on a discharge tray (not shown). Discharged.

In the above example, the surface treatment of the coat film 14 is controlled by the temperature control of the thermal head 46 (heating means).
However, in the present invention, the control of the surface treatment by the thermal head 46 is not limited to this. For example, various treatment conditions such as heating time, pressing time, pressing force, and surface roughness of the heating part are controlled. Thus, the surface roughness of the coating film 14 may be controlled according to the glossiness data.

Of course, a plurality of these processing conditions including the heating temperature may be controlled in combination.
For example, the pressing force of the thermal head 46 is set in a stepwise manner, and a condition setting table is set according to the combination of the pressing force and the coating film 14, and the target glossiness (surface roughness Ra) is set. ) To set (select) the pressing force of the thermal head 46, and the surface treatment conditions such as the heating temperature may be set under this pressing force. Alternatively, as described above, a plurality of thermal heads 46 having different surface roughnesses of the heating unit are prepared, and a condition setting table is set according to the combination of each thermal head and the coating film 14, The thermal head 46 to be used may be selected according to the target glossiness (surface roughness Ra), and the surface treatment conditions such as the heating temperature for each region may be set using the condition setting table.

  In any case, the condition setting table is created by knowing the relationship between the processing conditions such as the pressing force and the processing time and the surface roughness Ra of the coating film 14 through, for example, experiments or simulations performed in advance, and the control unit It may be set to 26.

  Although the image forming method and the image forming apparatus of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various improvements and modifications may be made without departing from the spirit of the present invention. Of course.

For example, in the illustrated example, as a preferred embodiment, gloss data that shows different glossiness for each part depending on the pattern is used, and in accordance with this, local control is performed using a thermal head, and an image part is displayed. However, the present invention is not limited to this, and the present invention is not limited to this. Using uniform gloss data on the entire surface, and performing uniform surface treatment on the entire surface to make the image glossy. It may be given.
Also in this aspect, by selecting the coating film and setting the surface treatment conditions, it is possible to impart a suitable glossiness according to the pattern etc. with a much higher degree of freedom than in the past. A high-quality image can be formed.

Further, in the illustrated example, a coating film having a smooth surface was formed on the recording medium, and this was subjected to surface treatment according to glossiness data, and roughening the surface of the coating film, In the present invention, the method for forming irregularities on the coating film by surface treatment is not limited thereto. For example, conversely, a coat film having a rough surface may be formed, and the coat film having a surface roughness corresponding to glossiness data may be formed by reducing unevenness by heat treatment or the like.
Further, the surface of the coating film is not limited to the method using the above-described thermal head, and the concave portion is formed by a heated needle using “Millipede” which is an information recording technology by IBM. A method of roughening the coat film by forming it is exemplified.

1 is a conceptual diagram of an embodiment of an image forming apparatus of the present invention that implements an example of an image forming method of the present invention. FIG. 2 is a conceptual diagram for explaining an image forming method of the present invention, and is a conceptual diagram showing an example of an image formed by the image forming apparatus 10 of FIG. 1. FIG. 2 is a conceptual diagram for explaining an image forming method of the present invention, and is a schematic cross-sectional view of a hard copy formed by the image forming apparatus 10 of FIG. 1, and conceptually explains physical factors of surface glossiness. It is. It is a figure which shows the flow of the image processing method implemented in the image forming apparatus 10 of FIG. (A) and (B) are conceptual diagrams of an example of a table used in the image forming method of the present invention, (A) is an example of a material setting table, and (B) is an example of a condition setting table. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Image forming apparatus 12 (Image) Recording medium 14 Coat film 16 (Media) supply part 18 Cutter 20 (Image) Recording part 22 (Coat film) Laminating part 24 Surface treatment part 26 Control part 28 Media roll 30 Supply roller pair 32, 34 Scanning and Conveying Roller Pair 36 (Inkjet) Recording Head 38 Laminating Means 39 Coat Film Roll 40 Laminate 42 Conveying Roller Pair 44 Discharge Roller Pair 46 Thermal Head 48 Platen Roller 60 Table

Claims (7)

A recording step of recording an image on an image recording layer of an image recording medium according to image data;
A material setting step for setting a coating film disposed on the image recording layer according to glossiness data indicating the glossiness of the reproduced image of the image data;
A condition setting step of setting surface treatment conditions of the coat film according to the set coat film and the gloss data;
And a processing step of performing a surface treatment of the coating film according to the determined surface treatment conditions.   The image forming method according to claim 1, wherein the glossiness data indicates a glossiness in each area of a reproduced image.   The image forming method according to claim 1, wherein the material setting step sets the coat film using a table with the gloss data and the coat film as parameters. The surface treatment in the treatment step uses a heating means for heating the surface of the coating film and a pressing means for pressing a pressing member on the surface of the coating film,
In the condition setting step, in addition to the glossiness data and the coat film, the heating temperature by the heating means, the heat treatment time, the pressing force by the pressing means, the surface roughness of the pressing member, and the pressing time by the pressing means The image forming method according to claim 1, wherein the surface treatment condition is set using a table having at least one of the parameters as a parameter.   The image forming method according to claim 4, wherein the heating unit heats the surface of the coat film by performing local control.   The image forming method according to claim 1, wherein a resolution of the image recording is an integer multiple of a resolution of the surface treatment. A medium supply unit for supplying an image recording medium;
An image recording unit for recording an image on an image recording layer of the image recording medium according to image data;
According to the glossiness data indicating the glossiness of the reproduced image of the image data, set a coat film disposed on the image recording layer, and according to the set coat film and the glossiness data, A control unit for setting surface treatment conditions of the coating film;
A coat film laminating unit that laminates the coat film set by the control unit on a surface of the image recording medium on which the image is recorded;
An image forming apparatus comprising: a surface treatment unit that performs surface treatment of the coat film according to a surface treatment condition of the coat film set by the control unit.

Images