JP6573007B2 - Structure manufacturing system - Google Patents

Description

  The present invention relates to a structure manufacturing system for manufacturing a structure.

  Conventionally, an electromagnetic wave heat conversion layer for converting electromagnetic waves into heat is formed by printing on a medium (for example, a heat-expandable sheet) having an expansion layer that expands and expands on one surface according to the amount of heat absorbed. Among them, there is known a method of manufacturing a structure by expanding a portion where an electromagnetic wave heat conversion layer is formed on a medium by irradiating with electromagnetic waves and accelerating (for example, see Patent Documents 1 and 2).

JP-A 64-28660 JP 2001-150812 A

  By the way, in order to manufacture such a structure, it is considered that an apparatus for forming an electromagnetic wave heat conversion layer on a medium and an apparatus for irradiating the medium with an electromagnetic wave are required. When manufacturing a structure using a combined system, no consideration is given to how to improve workability.

  An object of the present invention is to manufacture a structure that can improve workability when a structure is manufactured using a system that combines a device for forming an electromagnetic wave heat conversion layer and a device for irradiating electromagnetic waves. Is to provide a system.

A structure manufacturing system according to the present invention includes a printing apparatus having a print head for printing an electromagnetic wave heat conversion layer for converting electromagnetic waves to heat on a medium including an expansion layer that expands by heating , and the printing apparatus. An expansion device that is arranged in a line and expands the expansion layer in a region corresponding to the electromagnetic wave heat conversion layer by irradiating an electromagnetic wave from the irradiation unit toward the medium; and above the print head and the irradiation unit A slide mechanism that slides the top plate between a first position that covers the top and a second position that opens the top of the print head and the top of the irradiating unit; and the built-in the top plate A display unit that displays information on at least one of the printing device and the expansion device, and the slide mechanism moves the top plate in a direction in which the printing device and the expansion device are aligned. Sliding in the direction intersecting, characterized in that.
Moreover, the structure manufacturing system according to the present invention includes a printing apparatus having a print head for printing an electromagnetic wave heat conversion layer that converts electromagnetic waves into heat on a medium including an expansion layer that expands by heating, and the printing apparatus. An expansion device that is arranged side by side and expands the expansion layer in a region corresponding to the electromagnetic wave heat conversion layer by irradiating an electromagnetic wave from an irradiation unit toward the medium, and above the print head and the irradiation A slide mechanism that slides the top plate between a first position that covers the upper part of the printing unit and a second position that opens the upper part of the print head and the irradiation unit. Is characterized in that the top plate is slid in a direction intersecting the direction in which the printing device and the expansion device are arranged.

  ADVANTAGE OF THE INVENTION According to this invention, when manufacturing a structure using the system which combined the apparatus for forming an electromagnetic wave heat conversion layer, and the apparatus for irradiating electromagnetic waves, the workability | operativity can be improved.

It is a front view which shows typically the structure manufacturing system which concerns on one embodiment of this invention. It is a top view which shows typically the structure manufacturing system which concerns on one embodiment of this invention. It is a top view which shows typically the closed state before pulling out the top plate of the structure manufacturing system which concerns on one embodiment of this invention. It is a top view which shows typically the open state after pulling out the top plate of the structure manufacturing system which concerns on one embodiment of this invention. It is the perspective view which looked at the structure manufacturing system which concerns on one embodiment of this invention from the front upper left. It is the perspective view which looked at the structure manufacturing system which concerns on one embodiment of this invention from the back upper right. It is the perspective view which looked at the open state after pulling out the top plate of the structure manufacturing system which concerns on one embodiment of this invention from the front upper left. It is a front view which shows the structure manufacturing system which concerns on one embodiment of this invention. It is a right view which shows the structure manufacturing system which concerns on one embodiment of this invention. It is the perspective view which looked at the structure manufacturing system which concerns on one embodiment of this invention from the front upper right. It is the perspective view which looked at the flame | frame in one embodiment of this invention from the front upper right. It is sectional drawing which shows the medium for structure manufacture in one embodiment of this invention. It is sectional drawing which shows the structure in one embodiment of this invention. It is a flowchart for demonstrating the structure manufacturing method in one embodiment of this invention. It is a hardware structural example of the computer which can operate | move as a control unit in one embodiment of this invention. 1 is a perspective view showing a printing unit main body according to an embodiment of the present invention. It is sectional drawing which simplified the internal structure of the expansion | swelling unit in one embodiment of this invention.

Hereinafter, a structure manufacturing system according to an embodiment of the present invention will be described with reference to the drawings.
1A and 1B are a front view and a plan view schematically showing the structure manufacturing system 1. FIG.

1C and 1D are plan views schematically showing a closed state before the top plate 30 of the structure manufacturing system 1 is pulled out and an opened state after the top plate 30 is pulled out.
FIG.2 and FIG.3 is the perspective view which looked at the structure manufacturing system 1 from the front upper left, and the perspective view seen from the back upper right.

FIG. 4 is a perspective view of the opened state after the top plate 30 of the structure manufacturing system 1 is pulled out, as viewed from the upper left of the front.
5, 6, and 7 are a front view, a right side view, and a perspective view of the structure manufacturing system 1 as viewed from the upper right of the front.

FIG. 8 is a perspective view of the frame 60 as viewed from the front upper right.
1A to 8 and FIGS. 12 and 13 described later, the X direction (first direction) is the same as the direction in which the printing unit 10 and the expansion unit 20 are arranged (horizontal direction), and the Y direction ( (Second direction) is the same as the transport direction D in which the media M11 to M14 shown in FIGS. 12 and 13 are transported, the Z direction is the same as the vertical direction, and the X direction, the Y direction, and the Z direction are Are orthogonal to each other.

  As shown in FIGS. 1A to 7, the structure manufacturing system 1 includes a printing unit 10 that is an example of a printing apparatus, an expansion unit 20 that is an example of an expansion apparatus, a top plate 30, a display unit 40, and a control unit. A unit 50 and a frame 60 are provided.

  The printing unit 10 discharges the printing unit main body 300 shown in FIG. 12 to be described later, the suction unit 11 for sucking the media M11 to M13, and the media M12 to M14 that are printed on the media M11 to M13. And a discharge part 12 for the purpose. Although described in detail later, the printing unit 10 prints the front-side electromagnetic heat conversion layer 104 and the back-side electromagnetic heat conversion layer 106 shown in FIG. 9A on the media M11 and M13. Further, the printing unit 10 prints the color ink layer 105 shown in FIG. 9A on the medium M12.

  The expansion unit 20 includes a suction unit 21 for sucking the medium M14 and a discharge unit 22 for discharging the medium M14. The irradiation unit 24 illustrated in FIG. 13 emits electromagnetic waves toward the medium M14. As a result, the foamed resin layer 102 shown in FIG. 9A is expanded to produce the structure M15 shown in FIG. 9B.

  The printing unit 10 and the expansion unit 20 are arranged so as to be aligned in the first direction (X direction). The suction unit 11 of the printing unit 10 and the suction unit 21 of the expansion unit 20 are arranged on one side (back side) in the Y direction, which is the second direction intersecting the first direction, and the discharge unit of the printing unit 10. 12 and the discharge part 22 of the expansion unit 20 are arranged on the other side (front side) in the Y direction. In other words, the suction part 11 of the printing unit 10 and the suction part 21 of the expansion unit 20 are in one direction with respect to the top board 30 in the direction (Y direction) intersecting the X direction in which the printing unit 10 and the expansion unit 20 are arranged. The discharge portion 12 of the printing unit 10 and the discharge portion 22 of the expansion unit 20 are opposite to the one side with respect to the top plate 30 in the intersecting direction. Are arranged side by side in the X direction.

  Here, the front side is usually the side on which the operator 400 shown in FIGS. 1B to 1D faces the structure manufacturing system 1. Further, the front side can be said to be the lower side of the display content in the display unit 40 in the vertical direction. The rear side is the upper side in the vertical direction of the display content on the display unit 40. The display unit 40 may arbitrarily change the display direction. Here, since one side in the Y direction is the back side and the other side in the Y direction is the front side as described above, the X direction which is a horizontal direction orthogonal to (intersects with) the Y direction is also referred to as a horizontal direction or a horizontal direction. FIG. 1B shows an example of display contents (a painting depicting a mountain) displayed on the display unit 40.

  Note that it is desirable that the printing unit 10 and the expansion unit 20 be arranged so that they can be pulled out to the front side, for example, with the front panel 65 removed. Further, it is desirable that a control unit 50 described later is also arranged so as to be able to be pulled out, for example, on the front side.

  The top plate 30 is disposed so as to cover the upper part of the printing unit 10 and the expansion unit 20. The top plate 30 is closed by a pair of left and right slide mechanisms 67 of the frame 60 shown in FIG. 8, that is, a state in which the top of the printing unit 10 and the expansion unit 20 is covered, and an open state S shown in FIG. 1D. That is, it slides along the Y direction to the pulled-out state in which the upper part of the printing unit 10 and the expansion unit 20 is opened. That is, the top plate 30 can be slid by the slide mechanism 67 in a direction (Y direction) intersecting the X direction in which the printing unit 10 and the expansion unit 20 are arranged. The top plate 30 does not need to slide to a position where the entire upper part of the printing unit 10 and the expansion unit 20 is opened, but to a position where work such as maintenance of the printing unit 10 and the expansion unit 20 can be performed. It is desirable to be slidable. In FIG. 1D, the structure M15 manufactured using the structure manufacturing system 1 and the media M12 to M14, which are manufactured in the middle of manufacturing the structure M15, are shown together. In FIG. 1D, media M12 to M14 printed in the same vertical direction as the display content of the display unit 40 are output.

  The display unit 40 displays information regarding at least one of the printing unit 10 and the expansion unit 20. As shown in FIG. 1A, the upper surface of the display unit 40 is preferably located on the same plane as the upper surface of the top plate 30. The display unit 40 may include a touch panel for performing at least one of the printing unit 10 and the expansion unit 20.

  The center C2 in the X direction of the display unit 40 is incorporated at a position shifted to the expansion unit 20 side from the center C1 in the X direction of the top board 30. In other words, the display unit 40 is incorporated in a position shifted to the expansion unit 20 side from the center C1 of the top plate 30 in the X direction, that is, a position close to the end of the top plate 30 in the X direction. The display unit 40 may be incorporated at a position shifted from the center C1 of the top board 30 toward the printing unit 10 in the X direction. However, since the control unit 50 is located immediately below the printing unit 10 as will be described later, the operator 400 faces the expansion unit 20 in order to avoid the feet of the sitting operator 400 from coming into contact with the control unit 50. In this case, it is more desirable that the display unit 40 is shifted to the expansion unit 20 side from the viewpoint of the visibility of the operator 400 in this case.

  An operation unit that operates at least one of the printing unit 10 and the expansion unit 20 may be disposed instead of the display unit 40 or may be disposed together with the display unit 40. In this case, the operation unit has, for example, a button, a switch, a dial, and the like, and is preferably incorporated in the top plate 30 or disposed on the top plate 30.

  As shown in FIG. 1A, the control unit 50 is disposed immediately below the printing unit 10. Here, “directly below” means that at least a part of the control unit 50 is positioned below the center of the printing unit 10 in the X direction and the Y direction, and the printing unit is above the centers of the control unit 50 in the X direction and the Y direction. The case where at least part of 10 is located shall be said.

  The control unit 50 includes a control unit for controlling at least one of the printing unit 10, the expansion unit 20, and the display unit 40. The control unit 50 may include a power supply unit that supplies power to at least one of the printing unit 10, the expansion unit 20, and the display unit 40. As shown in FIGS. 2 and 5, an emergency stop button 51 for stopping the operation of at least one of the printing unit 10 and the expansion unit 20 is provided below the control unit 50. The emergency stop button 51 is preferably provided on the front side of the control unit 50 which is the operator 400 side.

  As shown in FIG. 6, the front end (left end in FIG. 6) of the control unit 50 is closer to the back side (right side in FIG. 6) than the front end of the printing unit 10 (and the expansion unit 20). It is placed behind. Further, as shown in FIG. 5, the end portion on the right side surface of the control unit 50 is positioned to the left of the end portion on the right side surface of the printing unit 10. Therefore, as shown in FIG. 7, the control unit 50 is difficult to visually recognize from the front side and the right side. In addition, when the control unit 50 is not visually recognized, it can be said that the design is improved by giving the operator 400 a cleaner appearance image than when the control unit 50 is visually recognized.

  As shown in FIG. 8, the frame 60 includes a pair of side bases 61, 61, a pair of side panels 62, 62, four movable legs 63, four fixed legs 64, and FIGS. A front panel 65 shown in FIG. 7, a back panel 66 shown in FIG. 3, a pair of slide mechanisms 67, 67, two upper connecting beams 68, 68, and three lower connecting beams 69, 69, 69 Have.

  The pair of side bases 61 and 61 have a trapezoidal frame shape (or a substantially rectangular frame shape) having a lower side longer than an upper side and rounded corners in a side view. The pair of side bases 61, 61 are provided with support beams 61a that support the end portions of the three lower connection beams 69 to which the printing unit 10 and the expansion unit 20 are fixed at the upper part so as to extend in the Y direction. Yes.

  The pair of side panels 62, 62 are provided from the upper end of the side base 61 to the support beam 61a so that the upper half of the hollow part of the side base 61 is more than the upper half and the hollow part is left below in the side view. It has been. Further, as shown in FIGS. 5 and 6, the pair of side panels 62 and 62 are provided from the upper end of the side base 61 to the lower side of the lower ends of the printing unit 10 and the expansion unit 20 in a side view. . The printing unit 10 and the expansion unit 20 do not protrude from the side base 61 and the side panel 62 except for the suction portions 11 and 21 in a side view. Note that, from the viewpoint of improving the design by giving the operator 400 a clean appearance image, it is desirable that the printing unit 10 and the expansion unit 20 are not easily seen from the left and right as described above. Moreover, although the side panel 62 may cover the whole hollow part of the side base 61, it is more desirable to cover only a part of the hollow part from the viewpoint of suppressing the material cost.

  The movable legs 63 are casters for enabling the structure manufacturing system 1 to be transported, and a total of four movable legs 63 are provided on each side base 61. A total of four fixed legs 64 are provided between the two movable legs 63 on each side base 61. The fixed leg 64 is provided so as to be adjustable in height at an upper position that allows transportation of the structure manufacturing system 1 and a lower position that makes contact with the ground and makes the structure manufacturing system 1 immovable. It is desirable.

  As shown in FIGS. 2, 5, and 7, the front panel 65 covers the front side of the printing unit 10 and the expansion unit 20 and opens at the discharge portions 12 and 22. Further, the front panel 65 is provided from the upper end of the side base 61 to below the lower ends of the printing unit 10 and the expansion unit 20 in order to improve the design like the side panel 62. The lower end of the front panel 65 is located at the same height as the lower ends of the pair of side panels 62 and 62 and the support beam 61a. The front panel 65 is preferably easy to attach and detach.

  A first surface 65 a located on the front side of the printing unit 10 in the front panel 65 protrudes more on the front side than a second surface 65 b located on the front side of the expansion unit 20. Therefore, there is a step between the first surface 65a and the second surface 65b that expand in the X direction and the Z direction, respectively. The first surface 65 a and the second surface 65 b of the front panel 65 are provided at a position deeper on the back side than the front side end of the side surface base 61.

  As shown in FIG. 3, the back panel 66 covers the back side of the printing unit 10 and the expansion unit 20 and opens at the suction portions 11 and 21. Further, the rear panel 66 is disposed between the pair of side bases 61 and 61 from the upper end of the side base 61 below the lower ends of the printing unit 10 and the expansion unit 20 in order to improve the design like the side panel 62. It is provided over. The lower end of the back panel 66 is positioned at the same height as the lower ends of the pair of side panels 62 and 62 and the support beam 61a. The back panel 66 is preferably easy to attach and detach.

  The back panel 66 is provided along the end of the side base 61 on the back side. Therefore, a curved portion 66 a that is curved along the curved portion at the upper end on the front side of the side surface base 61 is provided on the upper portion of the rear panel 66.

  The pair of slide mechanisms 67 and 67 shown in FIG. 8 are respectively provided at the upper ends of the opposing surfaces of the pair of side bases 61 and 61a. Each slide mechanism 67 includes a slider 67a fixed to a portion of the top plate 30 that protrudes downward from, for example, both ends in the X direction, and a guide rail 67b that guides the slider 67a to move in the Y direction. . Thereby, each slide mechanism 67 slides the top plate 30 in the Y direction as described above.

  The two upper connecting beams 68 and 68 are provided so as to be bridged between the pair of side bases 61 and 61 in order to connect the pair of side bases 61 and 61. One of the two upper coupling beams 68, 68 is fixed to the end on the back side of the upper ends of the pair of side bases 61, 61, and the other is at the lower part of the end on the front side of the guide rail 67b. The side base 61 and the guide rail 67b are fixed.

  The three lower connecting beams 69, 69, 69 are bridged between the support beams 61a, 61a of the pair of side bases 61, 61 in order to connect the pair of side bases 61, 61 in the Y direction. Are spaced apart from each other. The printing unit 10 and the expansion unit 20 are fixed to the upper part of the three lower connection beams 69, 69, 69. A control unit 50 is fixed to the lower part of the three lower connecting beams 69, 69, 69.

  One of the three lower connection beams 69, 69, 69 is fixed to the end portion on the back side of the support beam 61a, and the other two are arranged near the center of the support beam 61a in the Y direction. . The three lower connecting beams 69, 69, 69 are not provided on the front side of the support beam 61 a so as not to disturb the operation of the operator 400 during maintenance of the structure manufacturing system 1.

  The top plate 30 is positioned on the two upper connecting beams 68, 68, and the printing unit 10 and the expansion unit 20 are positioned on the three lower connecting beams 69, 69, 69. It can be said that the beam 68 and the lower connection beam 69 are also difficult to be visually recognized from the outside.

FIG. 9A is a cross-sectional view showing a medium M14 for manufacturing a structure in the present embodiment, and FIG. 9B is a cross-sectional view showing a structure M15 in the present embodiment.
The medium M14 shown in FIG. 9A is in a state before the foamed resin layer 102 is expanded by heating, and is inserted into the expansion unit 20 from the suction unit 21 of the expansion unit 20 as shown in FIG. , The foamed resin layer 102 expands by heating, and the structure M15 shown in FIG. 9B is manufactured.

  Further, the medium M11 in which the base material 101, the foamed resin layer 102, and the ink receiving layer 103 are sequentially laminated is inserted into the printing unit 10 from the suction unit 11 of the printing unit 10, and is, for example, in the printing unit main body 300 shown in FIG. The front electromagnetic wave heat conversion layer 104 is printed and discharged from the discharge unit 12. A color ink layer 105 is printed on the medium M12 on which the front electromagnetic wave heat conversion layer 104 is printed. Further, the back electromagnetic wave heat conversion layer 106 is printed on the medium M13 on which the color ink layer 105 is printed. The front electromagnetic wave heat conversion layer 104 and the back electromagnetic wave heat conversion layer 106 are examples of an electromagnetic wave heat conversion layer that converts electromagnetic waves into heat. The color ink layer 105 is an example of an image layer.

The base material 101 is made of a cloth such as paper or canvas, a panel material such as plastic, and the material is not particularly limited.
In the foamed resin layer 102, a thermal foaming agent (thermally expandable microcapsule) is dispersedly arranged in a binder which is a thermoplastic resin provided on the base material 101. Thereby, the foam expansion layer 102 expands and expands according to the amount of heat absorbed. The foamed resin layer 102 is an example of an expanded layer that expands when heated.

  The ink receiving layer 103 is formed to a thickness of, for example, 10 μm so as to cover the entire top surface of the foamed resin layer 102. The ink receiving layer 103 receives printing ink used in an ink jet printer, printing toner used in a laser printer, ballpoint pen and fountain pen ink, pencil graphite, and the like, and fixes it at least on the surface thereof. Therefore, it is possible to use a general-purpose ink receiving layer made of a suitable material and used for inkjet paper or the like.

  When the ink receiving layer 103, the front electromagnetic wave heat conversion layer 104, and the back electromagnetic wave heat conversion layer 106 are each stretchable, the foam receiving resin layer 102 and the ink are deformed by following the expansion of the foamed resin layer 102. Gaps are less likely to occur between the receiving layer 103, between the ink receiving layer 103 and the front electromagnetic wave heat conversion layer 104, and between the substrate 101 and the back electromagnetic wave heat conversion layer 106. If such a gap is generated, the amount of heat conduction from the front electromagnetic wave heat conversion layer 104 to the foamed resin layer 102 may be suppressed.

FIG. 10 is a flowchart for explaining the structure manufacturing method according to the present embodiment.
First, the above-described medium M11 is prepared, and then, on the first surface that is the surface of the medium M11 on which the expansion layer 102 is provided, that is, on the surface of the ink receiving layer 103, the expansion layer 102 is to be expanded. As the front electromagnetic wave heat conversion layer 104, black ink (black material) containing carbon black is printed by the ink jet method using the printing unit main body 300 which is a general-purpose ink jet printer shown in FIG. The layer 104 is formed (step S11: first surface electromagnetic wave heat conversion layer forming step). The medium M11 on which the front electromagnetic wave heat conversion layer 104 is formed is referred to as a medium M12.

  The printing unit main body 300 reads the gray scale value set for each coordinate, and prints a black material (black ink) based on the read value while controlling its density by, for example, area gradation. The front-side electromagnetic heat conversion layer 104 is formed of a material that can convert electromagnetic waves into heat energy more easily than the materials of the base material 101, the foamed resin layer 102, and the ink receiving layer 103 included in the medium M11. The front electromagnetic wave heat conversion layer 104 may be any layer that converts electromagnetic waves into heat, and may be a layer other than the layer formed by the printing unit main body 300.

  The same applies to the back electromagnetic wave heat conversion layer 106, but when the front electromagnetic wave heat conversion layer 104 is irradiated with the same amount of electromagnetic waves, the density (for example, area gradation) of the front electromagnetic wave heat conversion layer 104 is high. The foam resin layer 102 absorbs more heat energy in the region corresponding to. Basically, the foaming height of the foamed resin layer 102 has a positive correlation with the amount of heat absorbed by the foamed resin layer 102, so that the concentration of the front side electromagnetic wave heat conversion layer 104 and the back side electromagnetic wave heat conversion layer 106 eventually becomes higher. The deeper the portion formed, the higher the foam height of the foamed resin layer 102. Therefore, the density of the front electromagnetic wave heat conversion layer 104 is determined so as to correspond to the target height of the three-dimensional shape formed by the foamed resin layer 102 expanding and expanding together with the back electromagnetic wave heat conversion layer 106 described later.

  Next, three color inks of cyan C, magenta M, and yellow Y as coloring materials are printed on the first surface of the medium M12, that is, the surface on which the front electromagnetic wave heat conversion layer 104 is provided as shown in FIG. The color ink layer 105 is formed by printing by the ink jet method using the unit main body 300 (step S12: image layer forming step). The medium M12 on which the color ink layer 105 is formed is referred to as a medium M13.

  Here, when the black ink containing carbon black is used in the image layer forming step S12, the heat converted from the electromagnetic wave by the black ink portion is conducted to the expanded foam layer 102, so that the desired expanded state of the expanded resin layer 102 is obtained. You can't get it. Therefore, the black or gray hue in the color ink layer 105 is formed by a mixture of cyan C, magenta M, and yellow Y, or black ink that does not absorb thermal energy, that is, black K ink that does not contain carbon black. It is good to form using. Alternatively, as described above, in consideration of the heat absorbability of each part of the color ink layer 105, the heat absorbability of the front heat conversion layer 104, that is, the light and shade may be determined by subtracting this heat absorbability.

  Further, as the foamed resin layer 102 expands and the surface area of the foamed resin layer 102 increases, the density of the color ink layer 105 decreases. Compared to the visual color, it becomes lighter. For this reason, the color ink layer 105 may be set so as to have a desired color visually after the expansion of the foamed resin layer 102. That is, it is preferable that the portion where the expansion amount of the foamed resin layer 102 is set to be large increases the formation density of the color ink layer 105 formed on the portion.

  In the image layer forming step S12, a black ink layer may be formed by monochrome printing instead of forming the color ink layer 105. The color ink layer 105 and the black ink layer may be formed by means other than the printing unit main body 300 that is an ink jet printer, for example, a laser printer.

Next, a black ink (black material) containing carbon black on the second surface opposite to the first surface, that is, the surface on the side where the expansion layer 102 of the medium M11 is provided, that is, the back surface of the base material 101.
Is printed by the ink jet method using the printing unit main body 300 shown in FIG. 12, thereby forming the back electromagnetic wave heat conversion layer 106 (step S13: second surface electromagnetic wave heat conversion layer forming step). The medium M13 on which the back electromagnetic wave heat conversion layer 106 is formed is referred to as a medium M14. About the formation method of the back side electromagnetic wave heat conversion layer 106, it can be made to be the same as that of the above-mentioned front side electromagnetic wave heat conversion layer 104. FIG. One of the front-side electromagnetic heat conversion layer 104 and the back-side electromagnetic heat conversion layer 106 may be omitted. Further, the back electromagnetic wave heat conversion layer 106 may be formed before the front electromagnetic wave heat conversion layer 104 is formed, or after the front electromagnetic wave heat conversion layer 104 is formed and before the color ink layer 105 is formed.

  Next, the medium M14 is radiated with electromagnetic waves from the second surface side, that is, the back electromagnetic wave heat conversion layer 106 side (step S14: second surface side electromagnetic wave irradiation step), and then the first surface side, that is, the color ink layer 105. An electromagnetic wave is emitted from the side (step S15: first surface side electromagnetic wave irradiation step). In addition, you may perform 1st surface side electromagnetic wave irradiation process S15 before 2nd surface side electromagnetic wave irradiation process S14 or simultaneously with 2nd surface side electromagnetic wave irradiation process S14. Further, when one of the front electromagnetic wave heat conversion layer 104 and the back electromagnetic wave heat conversion layer 106 is omitted, the second surface electromagnetic wave irradiation step S14 or the first surface electromagnetic wave irradiation step S15 is omitted accordingly. .

  These 2nd surface side electromagnetic wave irradiation process S14 and 1st surface side electromagnetic wave irradiation process S15 are foamed resin layers by irradiating the electromagnetic wave of the wavelength range absorbed by the back side electromagnetic wave heat conversion layer 106 and the front side electromagnetic wave heat conversion layer 104 What is necessary is just the process of expanding 102 by heating, and it is performed by the irradiation part 24 shown in FIG. Thereby, in particular, the back electromagnetic wave heat conversion layer 106 and the front electromagnetic wave heat conversion layer 104 convert electromagnetic waves into heat, the heat is conducted to the thermal foaming agent contained in the foamed resin layer 102, and the thermal foaming agent causes an expansion reaction. . Therefore, the foamed resin layer 102 expands and expands to an extent corresponding to the black density of the back side electromagnetic wave heat conversion layer 106 and the front side electromagnetic wave heat conversion layer 104 in particular. A structure is manufactured from the medium M11 as described above. Note that even if the portion of the foamed resin layer 102 where neither the back electromagnetic wave heat conversion layer 106 nor the front electromagnetic wave heat conversion layer 104 is formed absorbs heat energy, the amount of heat is suppressed to a sufficiently small level. The height does not change or the change in height is sufficiently small compared to the portion where the back side electromagnetic heat conversion layer 106 and the front side electromagnetic heat conversion layer 104 are formed.

  Here, the wavelength of the electromagnetic wave irradiated toward the back electromagnetic wave heat conversion layer 106 and the front electromagnetic wave heat conversion layer 104 may be appropriately changed according to the back electromagnetic wave heat conversion layer 106 and the front electromagnetic wave heat conversion layer 104. Carbon black used for the back side electromagnetic wave heat conversion layer 106 and the front side electromagnetic wave heat conversion layer 104 has a visible light region (380 to 750 nm) and a center around a near infrared region (750 to 1400 nm) and an electromagnetic wave of other wavelengths. Easily absorbs electromagnetic waves having wavelengths including the mid-infrared region (1400 to 4000 nm). Materials other than carbon black may be used for the back electromagnetic wave heat conversion layer 106 and the front electromagnetic wave heat conversion layer 104, and an electromagnetic wave in a desired wavelength region may be irradiated from the entire wavelength region depending on the material used. Therefore, depending on the material, electromagnetic waves of other wavelengths such as the near ultraviolet region (200 to 380 nm), the far ultraviolet region (10 to 200 nm), the near infrared region, and the infrared region excluding the mid infrared region (4000 to 15000 nm) are irradiated. May be. In addition, said numerical value is an example and the boundary of a wavelength range is not restricted to this numerical value.

  As the control unit 50 described above, a computer 200 shown in FIG. 11, that is, a computer including a CPU (Central Processing Unit) 201, a storage unit 202, an input unit 203, an interface unit 204, and a recording medium driving unit 205. Can be used. These components are connected via a bus line 206, and exchange various data with each other.

  The CPU 201 is an arithmetic processing unit that controls the operation of the entire computer 200. The CPU 201 controls the manufacture of the structure by reading and executing the program for manufacturing the structure.

The storage unit 202 includes a ROM (Read Only Memory), a RAM (Random Access Memory), a hard disk, and the like.
The ROM is a read-only semiconductor memory in which a predetermined basic control program is recorded in advance. Note that as the ROM, a memory such as a flash memory in which stored data is nonvolatile when power supply is stopped may be used.

The RAM is a semiconductor memory that can be written and read at any time and used as a working storage area as necessary when the CPU 201 executes various control programs.
The hard disk stores various control programs executed by the CPU 201 and various data.

  The input unit 203 is, for example, a keyboard device or a mouse device. When operated by a user of the computer 200, the input unit 203 acquires various input information from the user associated with the operation content, and the acquired input information is stored in the CPU 201. Send to.

The interface unit 204 manages the exchange of various information with various devices.
The recording medium driving unit 205 is a device that reads various control programs and data recorded on the portable recording medium 207. The CPU 201 can read out and execute a predetermined control program recorded on the portable recording medium 207 via the recording medium driving unit 205 to perform each process of manufacturing the structure.

  Examples of the portable recording medium 207 include a CD-ROM (Compact Disc Read Only Memory), a DVD-ROM (Digital Versatile Disc Read Only Memory), and a flash memory equipped with a USB standard connector.

  In order to operate such a computer 200 as the control unit 50 of the structure manufacturing system 1, first, a control program for causing the CPU 201 to perform each process is created. The created control program is stored in advance in the hard disk device of the storage unit 202 or the portable recording medium 207. Then, when a predetermined instruction is given to the CPU 201, the control program is read and executed. As a result, the computer 200 operates as the control unit 50.

FIG. 12 is a perspective view showing a printing unit main body 300 in the present embodiment.
The printing unit main body 300 includes a carriage 301 that is disposed inside the printing unit 10 and is reciprocally movable in a direction indicated by a double-directional arrow a orthogonal to the medium conveyance direction. A print head 302 that executes printing and ink cartridges 303 (303w, 303c, 303m, and 303y) that store ink are attached to the carriage 301.

  The cartridges 303w, 303c, 303m, and 303y contain color inks of white W, cyan C, magenta M, and yellow Y, respectively. These cartridges are individually arranged independently, or each ink chamber is integrated in one housing, and the print head 302 having each nozzle for discharging each color ink is arranged in the cartridge. It is connected.

  The carriage 301 is slidably supported on the one hand by a guide rail 304, and is fixed to the toothed drive belt 305 on the other hand. As a result, the print head 302 and the ink cartridges 303 (303w, 303c, 303m, 303y) are reciprocated along with the carriage 301 in the direction perpendicular to the conveyance direction D, that is, the main scanning direction of printing, as indicated by the double arrow a in FIG. Is done.

  A flexible communication cable 306 is connected via the internal frame 307 between the print head 302 and the control unit 50 described above. Accordingly, print data and print control data are sent to the print head 302 through the flexible communication cable 306, and the print head 302 is controlled based on these data.

  A platen 308 is disposed below the inner frame 307 at a position facing the print head 302 so as to extend in the main scanning direction of the print head 302. The platen 308 constitutes a part of the medium conveyance path. The lower surface of each of the medium M11 on which the front electromagnetic wave heat conversion layer 104 is formed, the medium M12 on which the color ink layer 105 is formed, and the medium M13 on which the back electromagnetic wave heat conversion layer 106 is formed is in contact with the platen 308. In this state, the above-mentioned transport direction is caused by the suction roller pair 409 (the lower roller is behind the media M11, M12, and M13 and cannot be seen in FIG. 12) and the discharge roller pair 310 (the lower roller is not visible in the same manner). 12 is intermittently conveyed in the printing sub-scanning direction indicated by an arrow b in FIG. The suction roller 309 and the discharge roller pair 310 are controlled by the control unit 50.

  The control unit 50 controls the motor 311, the print head 302, the suction roller pair 309, and the discharge roller pair 310, thereby moving the print head 302 together with the carriage 301 via the drive belt 305 connected to the motor 311 in the main scanning direction. And the cyan C, magenta M, yellow Y color ink droplets and black K black ink droplets to the medium M12 by the print head 302 during the conveyance stop period of the medium M12. The color ink layer 105 is printed on the medium M12 by being ejected toward the medium M12. Further, during the stop period of the conveyance of the medium M11 or the medium M13, the black K ink droplets are ejected toward the medium M11 or the medium M13 by the print head 302, whereby the medium M11 has the front electromagnetic wave heat conversion layer 104 formed thereon. Printing is performed, and the back side electromagnetic heat conversion layer 106 is printed on the medium M13.

FIG. 13 is a simplified cross-sectional view of the internal structure of the expansion unit 20 in the present embodiment.
As illustrated in FIG. 13, the expansion unit 20 includes the above-described suction unit 21 and discharge unit 22, a housing 23, and an irradiation unit 24 provided inside the housing 23. In the expansion unit 20, the medium M14 sucked from the suction unit 21 is guided by the transport guide 21 b of the suction unit 21 and the transport guide 23 b of the housing 23, and is a transport roller of the suction unit 21 that is an example of a transport unit. It is conveyed by 21 a and the conveyance roller 23 a of the housing 23.

  As described above, the irradiation unit 24 irradiates the medium M14 with electromagnetic waves. The irradiation unit 24 is, for example, a halogen lamp and irradiates light in the near infrared region (750 to 1400 nm).

  In the present embodiment described above, the structure manufacturing system 1 is an electromagnetic wave heat conversion layer that converts electromagnetic waves into heat with respect to the media M11 and M13 including the foamed resin layer 102 that is an example of an expansion layer that expands by heating. A printing unit 10 that is an example of a printing apparatus that prints the front-side electromagnetic heat conversion layer 104 and the back-side electromagnetic heat conversion layer 106 that is an example, and the print unit 10 is arranged side by side (X direction), and is arranged on the medium M14. An expansion unit 20 that is an example of an expansion device that expands the foamed resin layer 102 by irradiating the electromagnetic wave toward the top, and a top plate 30 that is disposed so as to cover the print unit 10 and the expansion unit 20. .

By the way, the formation of the electromagnetic wave heat conversion layer and the irradiation of the electromagnetic wave are independently performed in the printing unit 10 and the expansion unit 20 which are independent from each other, so that the formation of the electromagnetic wave heat conversion layer and the irradiation of the electromagnetic wave are performed at a desired timing and exclusively. Therefore, it is possible to easily manufacture a structure in a desired foamed and expanded state. On the other hand, the operator 400 performs operations for inserting and removing the media M12, M13 or the media M14 from the printing unit 10 and the expansion unit 20, respectively. However, in the present embodiment, as described above, the printing unit 10 and the expansion unit 20 are arranged side by side, and the top plate 30 is positioned above the printing unit 10 and the expansion unit 20, The operator 400 can perform the operations of the printing unit 10 and the expansion unit 20 at the same level as each other without moving or slightly moving while facing the structure manufacturing system 1. Can be increased. Moreover, workability | operativity can also be improved by being able to mount the medium M11-M14 and the thing regarding another work on the top plate 30. FIG. Therefore, according to the present embodiment, electric apparatus for forming a wave-thermal conversion layer device for irradiating (printing unit 10) and an electromagnetic wave (expansion unit 20) and with a system that combines the structure of When manufacturing, the workability can be improved.

  In the present embodiment, a display unit 40 that displays information on at least one of the printing unit 10 and the expansion unit 20 is incorporated in the top board 30. As a result, the operator 400 can perform other operations on the top plate 30 while looking at the display unit 40 incorporated in the top plate 30, so that the workability can be further improved.

  In the present embodiment, the upper surface of the display unit 40 is located on the same plane as the upper surface of the top plate 30. Therefore, the work on the top plate 30 becomes easy and workability can be further improved.

  In the present embodiment, the display unit 40 is incorporated at a position close to the end of the top plate 30 in the lateral direction (X direction) in which the printing unit 10 and the expansion unit 20 are arranged. Thereby, since work can be performed in the space on the top plate 30 on the opposite side to the direction in which the display unit 40 is close to the end on the top plate 30, workability can be further improved.

  Further, in the present embodiment, the suction unit 11 of the printing unit 10 and the suction unit 21 of the expansion unit 20 intersect with the horizontal direction (X direction) in which the printing unit 10 and the expansion unit 20 are arranged (Y direction). ) In the horizontal direction on one side with respect to the top plate 30, and the discharge unit 12 of the printing unit 10 and the discharge unit 22 of the expansion unit 20 are in the intersecting direction (Y direction), It arrange | positions along with the horizontal direction (X direction) on the opposite side to said one side with respect to the top plate 30. As shown in FIG. Thereby, the medium can be inserted into and removed from the printing unit 10 and the expansion unit 20 from the same side. For this reason, it is possible to further improve workability, such as making it easier to confirm the printed state and the expanded state of foam from the front side where the discharge portions 12 and 22 are provided.

  In the present embodiment, the slide mechanisms 67 and 67 slide the top board 30 in a direction (Y direction) that intersects the horizontal direction (X direction) in which the printing unit 10 and the expansion unit 20 are arranged. In this way, the top plate 30 is slid and the upper part of the printing unit 10 and the expansion unit 20 is opened, so that maintenance such as ink replacement in the printing unit 10, jam removal in the printing unit 10 and the expansion unit 20, etc. Work can be done. Therefore, workability can be further improved.

  In the present embodiment, the control unit 50 is disposed directly below the printing unit 10. Therefore, compared with the case where it is arranged immediately below the expansion unit 20 that is likely to be hotter than the printing unit 10, it is possible to prevent the electronic components constituting the control unit 50 from being damaged due to the high temperature environment. .

  Although one embodiment of the present invention has been described above, the present invention includes the invention described in the claims and equivalents thereof. The invention described in the scope of claims at the beginning of the filing of the present application will be appended.

[Appendix 1]
A printing apparatus that prints an electromagnetic wave heat conversion layer that converts electromagnetic waves into heat for a medium including an expansion layer that expands by heating,
An expansion device that is arranged side by side with the printing device and expands the expansion layer by irradiating electromagnetic waves toward the medium;
A top plate arranged to cover the printing device and the expansion device;
A structure manufacturing system comprising:

[Appendix 2]
A display unit for displaying information on at least one of the printing device and the expansion device;
The display unit is incorporated in the top plate,
The structure manufacturing system according to supplementary note 1, wherein:

[Appendix 3]
The upper surface of the display unit is located on the same plane as the upper surface of the top plate,
The structure manufacturing system according to Supplementary Note 2, wherein

[Appendix 4]
The display unit is incorporated in a position near the end of the top plate in the lateral direction in which the printing device and the expansion device are arranged.
The structure manufacturing system according to Supplementary Note 2 or 3, wherein

[Appendix 5]
Each of the printing device and the expansion device has a suction portion for sucking the medium, and a discharge portion for discharging the medium,
The suction portion of the printing device and the suction portion of the expansion device are arranged in the lateral direction on one side with respect to the top plate in a direction intersecting the lateral direction in which the printing device and the expansion device are aligned. Arranged side by side,
The discharge portion of the printing apparatus and the discharge portion of the expansion device are arranged side by side along the lateral direction on the opposite side of the top plate from the one side in the intersecting direction. ,
The structure manufacturing system according to any one of appendices 1 to 4, characterized in that:

[Appendix 6]
A slide mechanism for sliding the top plate in a direction intersecting a lateral direction in which the printing device and the expansion device are arranged;
The structure manufacturing system according to any one of appendices 1 to 5, characterized in that:

[Appendix 7]
A control unit arranged directly below the printing apparatus;
The structure manufacturing system according to any one of appendices 1 to 6, characterized in that:

DESCRIPTION OF SYMBOLS 1 ... Structure manufacturing system, 10 ... Printing unit, 20 ... Expansion unit, 11, 21 ... Inhalation part, 12, 22 ... Discharge part, 30 ... Top plate, 40 ... Display unit, 50 ... Control unit, 6
0 ... frame, 67 ... slide mechanism, 300 ... printing unit main body, M11, M12, M13, M14 ... medium, M15 ... structure

Claims (8)

A printing apparatus having a print head for printing an electromagnetic wave heat conversion layer that converts electromagnetic waves into heat for a medium including an expansion layer that expands by heating;
An expansion device that is arranged side by side with the printing device and expands the expansion layer in a region corresponding to the electromagnetic wave heat conversion layer by irradiating an electromagnetic wave from an irradiation unit toward the medium;
A slide mechanism that slides the top plate between a first position that covers the print head and the irradiation unit, and a second position that opens the print head and the irradiation unit. When,
A display unit for displaying information on at least one of the printing device and the expansion device incorporated in the top plate;
With
The slide mechanism slides the top plate in a direction intersecting with a direction in which the printing device and the expansion device are arranged. The printing apparatus includes a suction unit for sucking the medium, and a discharge unit for discharging the medium.
The suction part is located on the first position side of the printing apparatus in a direction in which the top plate slides;
The structure manufacturing system according to claim 1, wherein the discharge unit is positioned on the second position side of the printing apparatus in a direction in which the top plate slides. The expansion device has a suction part for sucking the medium, and a discharge part for discharging the medium,
The suction portion is located on the first position side of the expansion device in a direction in which the top plate slides;
The said manufacturing part is located in the said 2nd position side of the said expansion | swelling apparatus in the direction in which the said top plate slides. The structure manufacturing system of Claim 1 or Claim 2 characterized by the above-mentioned. The printing apparatus includes a first suction part for sucking the medium, and a first discharge part for discharging the medium,
The expansion device has a second suction part for sucking the medium, and a second discharge part for discharging the medium,
The first suction part is located on the first position side of the printing apparatus in a direction in which the top plate slides,
The first discharge unit is located on the second position side of the printing apparatus in a direction in which the top plate slides,
The second suction part is located on the first position side of the expansion device in a direction in which the top plate slides,
The said 2nd discharge part is located in the said 2nd position side of the said expansion | swelling apparatus in the direction in which the said top plate slides , The structure manufacturing system of Claim 1 characterized by the above-mentioned. The slide mechanism is arranged to slide the top plate in the direction in which the first discharge portion and the second discharge portion are located, and to move the top plate to the second position. The structure manufacturing system according to claim 4, wherein the system is a structure manufacturing system. 6. The structure manufacturing system according to claim 4 , wherein the top plate has a size that does not cover an upper portion of the first suction portion and the second suction portion when the top plate is in the first position. . The first position is a position of an end portion in a sliding direction for the top plate to cover the print head and the irradiation unit,
Said 2nd position is a position of the end part of the slide direction for the said top plate to open | release the upper direction of the said print head and the said irradiation part.
The structure manufacturing system according to any one of claims 1 to 6, wherein the system is a structure manufacturing system. A printing apparatus having a print head for printing an electromagnetic wave heat conversion layer that converts electromagnetic waves into heat for a medium including an expansion layer that expands by heating;
An expansion device that is arranged side by side with the printing device and expands the expansion layer in a region corresponding to the electromagnetic wave heat conversion layer by irradiating an electromagnetic wave from an irradiation unit toward the medium;
A slide mechanism that slides the top plate between a first position that covers the print head and the irradiation unit, and a second position that opens the print head and the irradiation unit. When,
With
The slide mechanism slides the top plate in a direction intersecting the direction in which the printing device and the expansion device are arranged.
A structure manufacturing system characterized by that.