JP2018161791A - Expansion device, stereoscopic image forming system, method for expanding heat expansible sheet, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an expansion device capable of accurately expanding a heat expansible sheet, a stereoscopic image forming system, a method for expanding a heat expansible sheet, and a program.SOLUTION: In an expansion device 50, an irradiation section 60 irradiates a heat expansible sheet 100 with light. A conveyance motor 55 relatively moves the heat expansible sheet 100 and the irradiation section 60. A control board 70 acquires a temperature rising speed at a predetermined position based on light emitted from the irradiation section 60 when the irradiation section 60 performs preliminary irradiation with light before the irradiation section irradiates the heat expansible sheet 100 with light, sets relative movement speed of the heat expansible sheet 100 and the irradiation section 60 by the conveyance motor 55 based on the acquired temperature rising speed, and makes the irradiation section 60 perform irradiation with light while making the irradiation section relatively moving the heat expansible sheet 100 and the irradiation section 60 by the conveyance motor 55 with the set movement speed.SELECTED DRAWING: Figure 6

Description

  The present invention relates to an expansion device, a stereoscopic image forming system, a thermal expansion sheet expansion method, and a program.

  A technique for forming a stereoscopic image is known. For example, Patent Documents 1 and 2 disclose a method for forming a stereoscopic image using a thermally expandable sheet. Specifically, in the methods disclosed in Patent Documents 1 and 2, a pattern is formed on the back surface of the thermally expandable sheet with a material having excellent light absorption characteristics, and the formed pattern is irradiated with light by irradiation means. To heat. Thereby, the part in which the pattern in the thermally expansible sheet was formed expand | swells, and it rises, and a three-dimensional image is formed.

JP-A 64-28660 JP 2001-150812 A

  The intensity of light emitted from the irradiating means varies depending on factors such as fluctuations in the power supply voltage supplied to the irradiating means, individual differences among the irradiating means, and deterioration in performance of the irradiating means. When the intensity of light emitted from the irradiation unit varies, it is difficult to accurately expand the thermally expandable sheet, and there is a problem that it is difficult to form a stable stereoscopic image.

  The present invention is to solve the above-described problems, and provides an expansion device, a three-dimensional image forming system, a method of expanding a thermally expandable sheet, and a program capable of accurately expanding the thermally expandable sheet. The purpose is to do.

In order to achieve the above object, an expansion device according to the present invention comprises:
An irradiation means for irradiating the thermally expandable sheet with light;
Moving means for relatively moving the thermally expandable sheet and the irradiation means;
When the irradiation means preliminarily irradiates light prior to irradiating the thermally expansible sheet, the temperature increase rate at a predetermined position is determined based on the light irradiated from the irradiation means. Acquisition means for acquiring;
Setting means for setting a relative moving speed of the thermally expandable sheet and the irradiation means by the moving means based on the rising speed of the temperature acquired by the acquiring means;
Control means for irradiating the irradiation means with light while relatively moving the thermally expandable sheet and the irradiation means by the moving means at the moving speed set by the setting means;
It is characterized by providing.

  According to the present invention, the thermally expandable sheet can be expanded with high accuracy.

It is sectional drawing of the thermally expansible sheet which concerns on Embodiment 1 of this invention. It is a figure which shows the back surface of the thermally expansible sheet shown in FIG. 1 is a diagram illustrating a schematic configuration of a stereoscopic image forming system according to Embodiment 1. FIG. It is a block diagram which shows the structure of the terminal device which concerns on Embodiment 1. FIG. 1 is a perspective view illustrating a configuration of a printing apparatus according to a first embodiment. 1 is a cross-sectional view illustrating a configuration of an expansion device according to Embodiment 1. FIG. 2 is a block diagram illustrating a configuration of a control board of the expansion device according to Embodiment 1. FIG. It is a figure which shows a mode that the expansion | swelling apparatus performs expansion | swelling processing in Embodiment 1. FIG. It is a figure which shows the relationship between the power supply voltage supplied to the irradiation part in Embodiment 1, and the foaming height of a thermally expansible sheet. It is a figure which shows the relationship between the power supply voltage supplied to the irradiation part in Embodiment 1, and the temperature rise rate of a reflecting plate. It is a figure which shows the relationship between the moving speed of the irradiation part in Embodiment 1, and the foaming height of a thermally expansible sheet. 3 is a flowchart illustrating a flow of stereoscopic image formation processing in the first embodiment. (A)-(e) is a figure which shows a mode that a stereo image is formed in the thermally expansible sheet | seat shown in FIG. 3 is a flowchart showing a flow of processing executed by the expansion device according to the first embodiment. 4 is a flowchart showing a flow of pre-heat treatment executed by the expansion device according to the first embodiment. It is sectional drawing which shows the structure of the expansion apparatus which concerns on Embodiment 2 of this invention. It is a figure which shows the structure of the irradiation part in the expansion | swelling apparatus shown in FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals.

(Embodiment 1)
<Thermal expansion sheet 100>
FIG. 1 shows a configuration of a thermally expandable sheet 100 for forming a stereoscopic image by the stereoscopic image forming system 1 according to the present embodiment. The thermally expandable sheet 100 is a medium on which a three-dimensional image is formed by expanding a preselected portion by heating. A stereoscopic image is a three-dimensional image formed by expanding a part of a sheet in a direction perpendicular to the sheet in a two-dimensional sheet.

  As shown in FIG. 1, the thermally expandable sheet 100 includes a base material 101, a thermally expandable layer 102, and an ink receiving layer 103 in this order. FIG. 1 shows a cross section of the thermally expandable sheet 100 before a stereoscopic image is formed, that is, in a state where no part is expanded.

  The substrate 101 is a sheet-like medium that is the basis of the thermally expandable sheet 100. The substrate 101 is a support that supports the thermal expansion layer 102 and the ink receiving layer 103, and plays a role of maintaining the strength of the thermal expansion sheet 100. As the substrate 101, for example, a general printing paper can be used. Alternatively, the material of the base material 101 may be a cloth such as synthetic paper or canvas, or a plastic film such as polypropylene, polyethylene terephthalate (PET), or polybutylene terephthalate (PBT), and is not particularly limited.

  The thermal expansion layer 102 is laminated on the upper side of the base material 101 and is a layer that expands when heated to a specified expansion temperature or higher. The thermal expansion layer 102 includes a binder and a thermal expansion agent dispersedly disposed in the binder. The binder is a thermoplastic resin such as a vinyl acetate polymer or an acrylic polymer. The thermal expansion agent is a thermally expandable microcapsule having a particle diameter of about 5 to 50 μm in which a substance that vaporizes at a low boiling point such as propane and butane is encapsulated in an outer shell of a thermoplastic resin. When the thermal expansion agent is heated to a temperature of about 80 ° C. to 120 ° C., for example, the contained substance is vaporized, and foamed and expanded by the pressure. In this way, the thermal expansion layer 102 expands according to the amount of heat absorbed. The thermal expansion agent is also called a foaming agent.

  The ink receiving layer 103 is a layer that is laminated on the upper side of the thermal expansion layer 102 to absorb and receive ink. The ink receiving layer 103 receives printing ink used in an ink jet printer, printing toner used in a laser printer, ballpoint pen or fountain pen ink, pencil graphite, and the like. The ink receiving layer 103 is formed of a suitable material for fixing them to the surface. As a material of the ink receiving layer 103, for example, a general-purpose material used for ink jet paper can be used.

  In FIG. 2, the back surface of the thermally expansible sheet 100 is shown. The back surface of the thermally expandable sheet 100 is a surface on the base material 101 side of the heat expandable sheet 100 and corresponds to the back surface of the base material 101. On the other hand, the surface of the thermally expandable sheet 100 is a surface of the thermally expandable sheet 100 on the ink receiving layer 103 side and corresponds to the surface of the ink receiving layer 103.

  As shown in FIG. 2, a plurality of barcodes B are attached to the back surface of the thermally expandable sheet 100 along the edge thereof. The barcode B is an identifier for identifying the thermally expandable sheet 100, and is information indicating that the thermally expandable sheet 100 is a dedicated sheet for forming a stereoscopic image. The barcode B is an identifier that is read by the expansion device 50 of the stereoscopic image forming system 1 to be described later and determines whether or not the thermally expandable sheet 100 can be used in the expansion device 50.

<Stereoscopic image forming system 1>
Next, the stereoscopic image forming system 1 for forming a stereoscopic image on the thermally expandable sheet 100 will be described with reference to FIG. As illustrated in FIG. 3, the stereoscopic image forming system 1 includes a terminal device 30, a printing device 40, and an expansion device 50.

  The terminal device 30 is an information processing device such as a personal computer, a smartphone, or a tablet, and is a control unit that controls the printing device 40 and the expansion device 50. As illustrated in FIG. 4, the terminal device 30 includes a control unit 31, a storage unit 32, an operation unit 33, a display unit 34, a recording medium drive unit 35, and a communication unit 36. These units are connected by a bus for transmitting signals.

  The control unit 31 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory). In the control unit 31, the CPU reads a control program stored in the ROM and controls the operation of the entire terminal device 30 while using the RAM as a work memory.

  The storage unit 32 is a nonvolatile memory such as a flash memory or a hard disk. The storage unit 32 stores a program or data executed by the control unit 31, and color image data, front surface foaming data, and back surface foaming data printed by the printing apparatus 40.

  The operation unit 33 includes input devices such as a keyboard, a mouse, a button, a touch pad, and a touch panel, and receives an operation from the user. The user can input an operation for editing the color image data, the front surface foam data and the back surface foam data, an operation for the printing device 40 or the expansion device 50, and the like by operating the operation unit 33.

  The display unit 34 includes a display device such as a liquid crystal display or an organic EL (Electro Luminescence) display, and a display drive circuit that displays an image on the display device. For example, the display unit 34 displays color image data, front surface foam data, and back surface foam data. In addition, the display unit 34 displays information indicating the current state of the printing device 40 or the expansion device 50 as necessary.

  The recording medium driving unit 35 reads a program or data recorded on a portable recording medium. The portable recording medium is a CD (Compact Disc) -ROM, a DVD (Digital Versatile Disc) -ROM, a flash memory equipped with a USB (Universal Serial Bus) standard connector, or the like. For example, the recording medium driving unit 35 reads out and acquires color image data, front surface foaming data, and back surface foaming data from a portable recording medium.

  The communication unit 36 includes an interface for communicating with external devices including the printing device 40 and the expansion device 50. The terminal device 30 is connected to the printing device 40 and the expansion device 50 via a flexible cable, a wired LAN (Local Area Network) or the like, or a wireless LAN, Bluetooth (registered trademark), or the like. The communication unit 36 communicates with the printing device 40 and the expansion device 50 according to at least one of these communication standards under the control of the control unit 31.

<Printer 40>
The printing device 40 is a printing unit that prints an image on the front or back surface of the thermally expandable sheet 100. The printing apparatus 40 is an ink jet printer that prints an image using a method in which ink is atomized and sprayed directly onto a printing medium.

  FIG. 5 shows a detailed configuration of the printing apparatus 40. As shown in FIG. 5, the printing apparatus 40 includes a carriage 41 that can reciprocate in the main scanning direction D2 (X direction) orthogonal to the sub-scanning direction D1 (Y direction), which is the direction in which the thermally expandable sheet 100 is conveyed. Is provided.

  A print head 42 that executes printing and an ink cartridge 43 (43k, 43c, 43m, 43y) that stores ink are attached to the carriage 41. The ink cartridges 43k, 43c, 43m, and 43y contain black K, cyan C, magenta M, and yellow Y color inks, respectively. Each color ink is ejected from the corresponding nozzle of the print head 42.

  The carriage 41 is slidably supported on the guide rail 44 and is sandwiched between the drive belts 45. The carriage 41 moves in the main scanning direction D2 together with the print head 42 and the ink cartridge 43 when the driving belt 45 is driven by the rotation of the motor 45m.

  A platen 48 is provided below the frame 47 at a position facing the print head 42. The platen 48 extends in the main scanning direction D2, and constitutes a part of the conveyance path of the thermally expandable sheet 100. A feed roller pair 49a (lower roller is not shown) and a discharge roller pair 49b (lower roller is not shown) are provided in the conveyance path of the thermally expandable sheet 100. The paper feed roller pair 49a and the paper discharge roller pair 49b convey the thermally expandable sheet 100 supported by the platen 48 in the sub-scanning direction D1.

  The printing device 40 is connected to the terminal device 30 via a flexible communication cable 46. The terminal device 30 controls the print head 42, the motor 45m, the paper feed roller pair 49a, and the paper discharge roller pair 49b via the flexible communication cable 46. More specifically, the terminal device 30 controls the paper feed roller pair 49a and the paper discharge roller pair 49b to convey the thermally expandable sheet 100. Further, the terminal device 30 rotates the motor 45m to move the carriage 41, and conveys the print head 42 to an appropriate position in the main scanning direction D2.

  The printing device 40 acquires image data from the terminal device 30 and executes printing based on the acquired image data. More specifically, the printing apparatus 40 acquires color image data, front surface foam data, and back surface foam data as image data. The color image data is data indicating a color image to be printed on the surface of the thermally expandable sheet 100. The printing apparatus 40 prints a color image by ejecting each ink of cyan C, magenta M, and yellow Y toward the thermally expandable sheet 100 on the print head 42.

  On the other hand, the surface foaming data is data indicating a portion to be foamed and expanded on the surface of the thermally expandable sheet 100. The back surface foaming data is data indicating a portion that is foamed and expanded on the back surface of the thermally expandable sheet 100. The printing apparatus 40 causes the black K ink containing carbon black to be ejected toward the thermally expandable sheet 100 on the print head 42 to print a grayscale image (dark pattern). Black ink containing carbon black is an example of a material that converts light into heat.

<Inflator 50>
The expansion device 50 irradiates light on the front surface or the back surface of the thermally expandable sheet 100 to generate heat on the gray image printed on the front surface or the back surface of the thermally expandable sheet 100, and the gray image in the thermally expandable sheet 100. Is an expansion unit that expands the printed portion.

  FIG. 6 schematically shows the configuration of the expansion device 50. In FIG. 6, the X direction corresponds to the width direction of the expansion device 50, the Y direction corresponds to the longitudinal direction of the expansion device 50, and the Z direction corresponds to the vertical direction. The X direction, the Y direction, and the Z direction are orthogonal to each other. As illustrated in FIG. 6, the expansion device 50 includes a housing 51, an insertion unit 52, a tray 53, a ventilation unit 54, a conveyance motor 55, a conveyance rail 56, an irradiation unit 60, and a power supply board 69. And a control board 70.

  The insertion part 52 is provided with an openable door, and is a mechanism for inserting the thermally expandable sheet 100 that is a target for forming a stereoscopic image into the housing 51. The user opens the insertion portion 52, slides the tray 53 and pulls it out to the near side, and then installs the thermally expandable sheet 100 on the tray 53 with the front surface or back surface thereof facing up. At this time, the user installs the thermally expandable sheet 100 on the tray 53 so that the end portion to which the barcode B of the thermally expandable sheet 100 is attached is located on the back side. Then, when the tray 53 on which the thermally expandable sheet 100 is installed is returned to the inside of the casing 51 and the insertion unit 52 is closed, the thermally expandable sheet 100 is disposed at a position where the irradiation unit 60 can irradiate light. .

  The tray 53 is a mechanism for installing the thermally expandable sheet 100 at an appropriate position in the housing 51. The tray 53 is fixed by suppressing the edge portions of the four sides of the installed thermally expandable sheet 100 from above. The tray 53 includes a sensor that detects the thermally expandable sheet 100, whether or not the thermally expandable sheet 100 is installed, and when the thermally expandable sheet 100 is installed, of the thermally expandable sheet 100. Detect the size.

  The ventilation unit 54 is provided at the end on the far side of the expansion device 50 and functions as a ventilation means for ventilating the inside of the expansion device 50. The ventilation unit 54 includes at least one exhaust fan, and vents the inside of the casing 51 by discharging the air inside the casing 51 to the outside. The air in the casing 51 is supplied from the outside by the cooling unit 64 and is discharged to the outside by the ventilation unit 54. The ventilation unit 54 circulates the air inside the casing 51 by discharging the air supplied from the outside by the cooling unit 64 to the outside.

  The conveyance motor 55 is a stepping motor that operates in synchronization with, for example, pulse power, and moves the irradiation unit 60 along the front or back surface of the thermally expandable sheet 100. Inside the casing 51, a transport rail 56 is provided in the Y direction, that is, in a direction parallel to the front or back surface of the thermally expandable sheet 100. The irradiation unit 60 is attached to the transport rail 56 so as to be able to move along the transport rail 56. The irradiation unit 60 reciprocates along the transport rail 56 while keeping the distance from the thermally expandable sheet 100 constant by using the driving force accompanying the rotation of the transport motor 55 as a power source. The conveyance motor 55 functions as a moving unit that relatively moves the thermally expandable sheet 100 and the irradiation unit 60.

  If demonstrating it concretely, the irradiation part 60 will be the 1st position P1 corresponding to the edge part of the back | inner side of the thermally expansible sheet 100, and the 2nd position corresponding to the edge part of the near side of the thermally expansible sheet 100. Reciprocate between P2. The first position P1 is an initial position (home position) of the irradiation unit 60. The irradiation unit 60 stands by at the first position P1 when the expansion device 50 is not operating.

  The first position P1 is a position on the side opposite to the side where the insertion part 52 is provided in the casing 51, and the second position P2 is a position on the side where the insertion part 52 is provided in the casing 51. Position. In other words, the first position P1 is a position farther from the end on the side where the thermally expandable sheet 100 is inserted in the expansion device 50 than the second position P2. Thus, since the initial position of the irradiation unit 60 is provided on the opposite side of the insertion unit 52 in the housing 51, the user can insert the thermal expandable sheet 100 into the housing 51. You can avoid touching. Therefore, the user can install the thermally expandable sheet 100 smoothly.

  The irradiation unit 60 is a mechanism that irradiates light, and functions as an irradiation unit that irradiates light to the thermally expandable sheet 100 disposed on the tray 53. As shown in FIG. 6, the irradiation unit 60 includes a lamp heater 61, a reflection plate 62, a temperature sensor 63, a cooling unit 64, and a barcode reader 65.

  The lamp heater 61 includes, for example, a halogen lamp, and has a near infrared region (wavelength 750 to 1400 nm), a visible light region (wavelength 380 to 750 nm), or a mid infrared region (with respect to the thermally expandable sheet 100). Irradiation with light having a wavelength of 1400 to 4000 nm is performed. When light is applied to the heat-expandable sheet 100 on which a gray-scale image is printed with black ink containing carbon black, light is more efficiently emitted in the portion where the gray-scale image is printed than in the portion where the gray-scale image is not printed. Converted into heat. Therefore, the portion of the thermally expandable sheet 100 on which the grayscale image is printed is mainly heated and expands when the temperature of the thermal expansion agent reaches the temperature at which expansion starts.

  The reflection plate 62 is an irradiated body that receives the light emitted from the irradiation unit 60 and is a mechanism that reflects the light emitted from the lamp heater 61 toward the thermally expandable sheet 100. The reflection plate 62 is disposed so as to cover the upper side of the lamp heater 61 and reflects light emitted upward from the lamp heater 61 toward the lower side. The light that is irradiated from the lamp heater 61 can be efficiently irradiated to the thermally expandable sheet 100 by the reflecting plate 62.

  The temperature sensor 63 is a thermocouple, a thermistor, or the like, and functions as a measurement unit that measures the temperature of the reflection plate 62. The temperature sensor 63 measures the temperature of the reflection plate 62 when the lamp heater 61 is irradiating light. Since the reflection plate 62 receives light emitted from the lamp heater 61, the reflection plate 62 changes according to the intensity of light emitted by the lamp heater 61, that is, the magnitude of light energy. Therefore, the temperature of the reflection plate 62 can be used as an index of the intensity of light emitted from the lamp heater 61.

  The cooling unit 64 is provided on the upper side of the reflection plate 62 and functions as a cooling unit that cools the inside of the expansion device 50. The cooling unit 64 includes at least one air supply fan, and cools the irradiation unit 60 by sending air to the irradiation unit 60 from the outside of the expansion device 50. More specifically, the cooling unit 64 sucks air outside the expansion device 50 from an air supply port provided in the upper part of the cooling unit 64 and sends the sucked air to the irradiation unit 60. The air sucked in by the cooling unit 64 is supplied to the reflecting plate 62, and the reflecting plate 62 is air-cooled. The air sucked by the cooling unit 64 is supplied to the inside of the expansion device 50 through the irradiation unit 60, and each part in the casing 51 including the thermally expandable sheet 100 installed on the tray 53 is cooled. .

  The barcode reader 65 functions as a reading unit that reads the barcode B attached to the back surface of the thermally expandable sheet 100. The barcode reader 65 reads the barcode B attached to the back surface of the thermally expandable sheet 100 via a reflector (not shown) when the thermally expandable sheet 100 is inserted into the expansion device 50 with the surface facing upward. . The reflector is a reflecting mirror that is installed at the end on the far side of the tray 53 and allows the barcode reader 65 to read the barcode B from the opposite side. On the other hand, when the thermally expandable sheet 100 is inserted into the expansion device 50 with the back surface facing upward, the barcode reader 65 converts the barcode B attached to the back surface of the thermally expandable sheet 100 into a reflector. Read directly without intervention.

  The expansion device 50 determines whether the medium installed on the tray 53 can be used by the expansion device 50 according to whether or not the barcode B can be read by the barcode reader 65. If a medium that is not a dedicated sheet for forming a stereoscopic image is inserted into the expansion device 50, the expansion device 50 may not operate normally. Therefore, the expansion device 50 does not start the light irradiation process by the irradiation unit 60 when the barcode B cannot be read by the barcode reader 65. Thereby, malfunction of expansion device 50 is controlled.

  The power supply board 69 includes a power supply IC (Integrated Circuit) or the like, and generates and supplies necessary power to each part in the expansion device 50. For example, the ventilation unit 54, the conveyance motor 55, the lamp heater 61, and the cooling unit 64 operate by obtaining electric power from the power supply board 69.

  The control board 70 is provided on a board arranged at the lower part of the casing 51 and controls the operation of each part of the expansion device 50. As shown in FIG. 7, the control board 70 includes a control unit 71, a storage unit 72, a timer unit 73, and a communication unit 74.

  The control unit 71 includes a CPU, a ROM, and a RAM, and is connected to each unit of the expansion device 50 via a system bus that is a transmission path for transferring commands and data. The CPU is, for example, a microprocessor or the like, and is a central processing unit that executes various processes and operations. In the control unit 71, the CPU reads the control program stored in the ROM and controls the operation of the entire expansion device 50 while using the RAM as a work memory.

  The storage unit 72 is a nonvolatile memory such as a flash memory or a hard disk. The storage unit 72 stores a program or data executed by the control unit 71 and data generated or acquired by the control unit 71 performing various processes. The timekeeping unit 73 includes a timekeeping device such as an RTC (Real Time Clock), and continues time keeping even when the power of the expansion device 50 is off.

  The communication unit 74 includes an interface for communicating with the terminal device 30. The communication unit 74 communicates with the terminal device 30 in a wired or wireless manner under the control of the control unit 71. For example, the communication unit 74 acquires from the terminal device 30 an instruction to start the light irradiation process input from the user in the terminal device 30. In addition, the communication unit 74 transmits information indicating the current state of the expansion device 50 to the terminal device 30.

  As shown in FIG. 7, the control unit 71 functionally includes an expansion processing unit 81 that functions as expansion processing means, and a speed determination unit 82 that functions as speed determination means. In the control unit 71, the CPU functions as each of these units by reading out a program stored in the ROM into the RAM and executing and controlling the program.

  The expansion processing unit 81 performs an expansion process for expanding the thermally expandable sheet 100. Specifically, the expansion processing unit 81 expands the thermally expandable sheet 100 by irradiating the irradiation unit 60 with light while moving the irradiation unit 60 by the transport motor 55.

  FIG. 8 shows a state in which the expansion device 50 performs the expansion process. In the expansion process, the expansion processing unit 81 supplies a power supply voltage to the irradiation unit 60 to turn on the lamp heater 61. And the expansion | swelling process part 81 moves the irradiation part 60 toward the 2nd position P2 from the 1st position P1 by driving the conveyance motor 55 in the state which is irradiating the irradiation part 60 with light. . As described above, the expansion processing unit 81 moves the irradiation unit 60 from end to end of the thermally expandable sheet 100 to irradiate light over the entire surface or back surface of the thermally expandable sheet 100.

  When light is irradiated by the irradiation unit 60, a portion of the thermally expandable sheet 100 on which a grayscale image including carbon black is printed generates heat, and expands when heated to a specified expansion temperature. The specified expansion temperature is a temperature at which the thermal expansion agent contained in the thermal expansion layer 102 starts to expand, and is, for example, a temperature of about 80 ° C. to 120 ° C. When the portion of the thermally expandable sheet 100 on which the grayscale image is printed is expanded, a stereoscopic image is formed on the thermally expandable sheet 100.

  In such expansion processing of the thermally expandable sheet 100, the intensity of light irradiated from the irradiation unit 60 varies depending on the power supply voltage supplied to the irradiation unit 60. More specifically, the light energy emitted from the lamp heater 61 changes by about 3.2 times the fluctuation rate of the power supply voltage supplied to the irradiation unit 60. Therefore, when the power supply voltage fluctuates, the intensity of light emitted from the irradiation unit 60 changes greatly, and the degree of expansion of the thermally expandable sheet 100 changes accordingly.

  In FIG. 9, the relationship between the power supply voltage supplied to the irradiation part 60 and the foaming height of the thermally expansible sheet 100 is shown. In FIG. 9, the vertical axis and the horizontal axis indicate the foaming height and the power supply voltage, respectively, by the rate of change. The foaming height of the thermally expandable sheet 100 means a height raised from the front surface or the back surface when the thermally expandable sheet 100 is heated and expanded. In addition, the numerical value in FIG. 9 is an example for facilitating understanding. The same applies to FIGS. 10 and 11.

  As shown in FIG. 9, when the power supply voltage supplied to the irradiation unit 60 varies, the foaming height of the thermally expandable sheet 100 varies according to the variation rate of the power supply voltage. Specifically, the foaming height of the thermally expandable sheet 100 varies greatly from the second power to the third power of the variation rate of the power supply voltage. Furthermore, the intensity of light emitted from the irradiation unit 60 varies not only due to fluctuations in the power supply voltage, but also due to individual differences in the lamp heater 61, deterioration in performance of the lamp heater 61, and the like. When the foaming height fluctuates in this manner, it is difficult to expand the thermally expandable sheet 100 to a desired height, and thus it is difficult to form an accurate stereoscopic image on the thermally expandable sheet 100.

  In order to suppress such variation in the foaming height of the thermally expandable sheet 100, the expansion device 50 is configured to irradiate the irradiation unit by the conveyance motor 55 during the pre-heat treatment (preheating) before the expansion processing unit 81 executes the expansion processing. 60 moving speed is adjusted. Therefore, the speed determination unit 82 determines the moving speed of the irradiation unit 60 by the transport motor 55 based on the temperature of the reflection plate 62 measured by the temperature sensor 63.

  Since the reflecting plate 62 receives light emitted from the lamp heater 61, the temperature of the reflecting plate 62 rises when the lamp heater 61 is turned on (turned on), and when the lamp heater 61 is turned off (turned off). descend. And since the degree of the temperature rise of the reflecting plate 62 when the lamp heater 61 is lit changes depending on the intensity of light emitted from the lamp heater 61, the power supply voltage supplied to the irradiation unit 60 It changes with fluctuations.

  FIG. 10 shows the relationship between the power supply voltage supplied to the irradiation unit 60 and the temperature rise rate of the reflector 62. As shown in FIG. 10, the temperature increase rate of the reflector 62 correlates with the power supply voltage supplied to the irradiation unit 60. Specifically, when the power supply voltage increases, the light energy emitted from the irradiation unit 60 increases, so the temperature rise rate of the reflector 62 increases, and when the power supply voltage decreases, the light emitted from the irradiation unit 60 increases. Since energy becomes small, the temperature increase rate of the reflector 62 decreases. Thus, the temperature increase rate of the reflecting plate 62 can be used as an index of the power supply voltage supplied to the irradiation unit 60 and the intensity of light irradiated from the irradiation unit 60.

  The speed determination unit 82 is a reflector based on the light emitted from the irradiation unit 60 when the irradiation unit 60 preliminarily irradiates the thermal expansive sheet 100 with light. It functions as an acquisition means for acquiring the temperature increase rate of 62. More specifically, the speed determination unit 82 acquires, as the temperature increase rate of the reflector 62, the increase value during the specified time of the temperature measured by the temperature sensor 63, that is, the increase temperature during the specified time. To do. The specified time is an arbitrary length of time. And the speed determination part 82 acquires the raise speed | rate of the temperature of the reflecting plate 62 according to rising temperature, and sets the moving speed of the irradiation part 60 based on a raise speed. The speed determination unit 82 functions as a setting unit that sets the moving speed of the irradiation unit 60.

  The moving speed of the irradiation unit 60 is a speed at which the irradiation unit 60 is moved from the first position P1 to the second position P2 when the thermally expandable sheet 100 is expanded. When the moving speed of the irradiation unit 60 changes, the moving time for the irradiation unit 60 to move from the first position P1 to the second position P2, that is, the irradiation time by the irradiation unit 60 changes. The amount of light applied to the part also changes. Therefore, the foaming height of the thermally expandable sheet 100 changes according to the moving speed of the irradiation unit 60.

  FIG. 11 shows the relationship between the moving speed of the irradiation unit 60 and the foaming height of the thermally expandable sheet 100 when light having a certain intensity is irradiated by the irradiation unit 60 moving at the moving speed. In FIG. 11, the vertical axis and the horizontal axis indicate the foaming height and the moving speed, respectively, with the rate of change. As shown in FIG. 11, the irradiation time becomes shorter as the moving speed of the irradiation unit 60 becomes higher, so the foaming height of the thermally expandable sheet 100 becomes lower. On the other hand, since the irradiation time becomes longer as the moving speed of the irradiation unit 60 becomes lower, the foaming height of the thermally expandable sheet 100 becomes higher. In this way, the foaming height of the thermally expandable sheet 100 can be adjusted by changing the moving speed of the irradiation unit 60.

  The speed determination unit 82 changes the moving speed of the irradiation unit 60 so as to cancel the fluctuation of the power supply voltage supplied to the irradiation unit 60 based on the relationship between the parameters shown in FIGS. 9 to 11. More specifically, the speed determination unit 82 has a temperature increase value larger than the first value than the case where the temperature increase value measured by the temperature sensor 63 during the specified time is the first value. When the value is 2, the moving speed of the irradiation unit 60 is determined to be higher. In other words, the speed determination unit 82 sets the moving speed of the irradiation unit 60 to a higher speed when the temperature increase rate of the reflector 62 is larger.

  More specifically, when the temperature rise value measured by the temperature sensor 63 is the first value that is relatively small, that is, when the temperature rise rate of the reflector 62 is relatively low, the lamp heater 61. The intensity of the light emitted from is relatively small. Therefore, the speed determination part 82 lengthens irradiation time by setting the moving speed of the irradiation part 60 relatively low. On the other hand, when the temperature increase value measured by the temperature sensor 63 is a relatively large second value, that is, when the temperature increase rate of the reflector 62 is relatively high, the lamp heater 61 The intensity of the irradiated light is relatively large. Therefore, the speed determination part 82 shortens irradiation time by setting the moving speed of the irradiation part 60 relatively high.

  Information for converting the temperature rise value into the moving speed is stored in advance in the storage unit 72 as a conversion table or a conversion formula. The speed determination unit 82 refers to the conversion table stored in the storage unit 72 or applies a conversion formula to determine the movement speed corresponding to the temperature increase value measured by the temperature sensor 63 of the irradiation unit 60. Determine as moving speed.

  The expansion processing unit 81 expands the thermally expandable sheet 100 by irradiating the irradiation unit 60 with light while moving the irradiation unit 60 at the moving speed determined by the speed determination unit 82 in this way. As described above, the moving speed of the irradiation unit 60 is adjusted so as to cancel the fluctuation of the power supply voltage supplied to the irradiation unit 60. Therefore, even if the power supply voltage fluctuates, the thermally expandable sheet 100 can be expanded to a desired height, and a stereoscopic image can be formed on the thermally expandable sheet 100 with high accuracy.

  By such an expansion process, the irradiation unit 60 reaches the second position P2. The expansion processing unit 81 moves the irradiation unit 60 from the second position P2 toward the first position P1, that is, returns the irradiation unit 60 to the initial position, and performs ventilation processing by the ventilation unit 54 as necessary. Or the cooling process by the cooling unit 64 is executed. If it demonstrates concretely, the expansion process part 81 will drive the ventilation part 54, and will discharge the air in the housing | casing 51 heated by the expansion process outside. Moreover, the expansion process part 81 drives the cooling part 64, and cools the irradiation part 60 and the thermally expansible sheet 100 heated by the expansion process.

<Stereoscopic image formation processing>
Regarding the flow of the stereoscopic image forming process executed in the stereoscopic image forming system 1 configured as described above, the flowchart shown in FIG. 12 and the cross-sectional views of the thermally expandable sheet 100 shown in FIGS. The description will be given with reference.

  First, the user prepares the thermally expandable sheet 100 before the stereoscopic image is formed, and specifies color image data, front surface foam data, and back surface foam data via the operation unit 33 of the terminal device 30. Then, the thermally expandable sheet 100 is inserted into the printing apparatus 40 with its surface facing upward. The printing apparatus 40 prints the photothermal conversion layer 104 on the surface of the inserted thermally expandable sheet 100 (step S1). The photothermal conversion layer 104 is a layer formed of a material that converts light into heat, specifically, black ink containing carbon black. The printing apparatus 40 discharges black ink containing carbon black onto the surface of the thermally expandable sheet 100 in accordance with the designated surface foaming data. As a result, a photothermal conversion layer 104 is formed on the ink receiving layer 103 as shown in FIG.

  Second, the user inserts the thermally expandable sheet 100 on which the light-to-heat conversion layer 104 is printed into the expansion device 50 with the surface thereof facing upward. The expansion device 50 irradiates the surface of the inserted thermally expandable sheet 100 with light by the irradiation unit 60 (step S2). The photothermal conversion layer 104 printed on the surface of the thermally expandable sheet 100 generates heat by absorbing the irradiated light. As a result, as shown in FIG. 13B, the portion of the thermally expandable sheet 100 on which the photothermal conversion layer 104 is printed rises and expands.

  Thirdly, the user inserts the thermally expandable sheet 100 whose surface has been heated and expanded into the printing apparatus 40 with its surface facing upward. The printing apparatus 40 prints the color ink layer 105 on the surface of the inserted thermally expandable sheet 100 (step S3). More specifically, the printing apparatus 40 ejects cyan C, magenta M, and yellow Y inks onto the surface of the thermally expandable sheet 100 in accordance with designated color image data. As a result, as shown in FIG. 13C, a color ink layer 105 is formed on the ink receiving layer 103 and the photothermal conversion layer 104.

  Note that the printing device 40 forms a mixed color ink of cyan C, magenta M, and yellow Y when printing a black or gray color image on the color ink layer 105, or carbon black. It is formed by further using black ink that does not contain. This avoids that the portion where the color ink layer 105 is formed is heated in the expansion device 50.

  Fourth, the user turns over the thermally expandable sheet 100 on which the color ink layer 105 has been printed, and inserts the sheet into the expansion device 50 with the back surface facing upward. The expansion device 50 irradiates the back surface of the inserted thermally expandable sheet 100 with light by the irradiation unit 60 and heats the thermally expandable sheet 100 from the back surface. Thereby, the expansion device 50 volatilizes the solvent contained in the color ink layer 105 and dries the color ink layer 105 (step S4). By drying the color ink layer 105, the thermally expandable sheet 100 is easily expanded in a later process.

  Fifth, the user inserts the thermally expandable sheet 100 on which the color ink layer 105 is printed into the printing apparatus 40 with the back surface thereof facing up. The printing apparatus 40 prints the photothermal conversion layer 106 on the back surface of the inserted thermally expandable sheet 100 (step S5). Similar to the photothermal conversion layer 104 printed on the surface of the thermally expandable sheet 100, the photothermal conversion layer 106 is a layer formed of a material that converts light into heat, specifically, black ink containing carbon black. . The printing apparatus 40 discharges black ink containing carbon black on the back surface of the thermally expandable sheet 100 according to the specified back surface foaming data. As a result, a photothermal conversion layer 106 is formed on the back surface of the substrate 101 as shown in FIG.

  Sixth, the user inserts the thermally expandable sheet 100 on which the light-to-heat conversion layer 106 is printed into the expansion device 50 with its back surface facing upward. The expansion device 50 irradiates the back surface of the inserted thermally expandable sheet 100 with light by the irradiation unit 60 (step S6). The photothermal conversion layer 106 printed on the back surface of the thermally expandable sheet 100 generates heat by absorbing the irradiated light. As a result, as shown in FIG. 13E, the portion of the thermally expandable sheet 100 where the light-to-heat conversion layer 106 is printed rises and expands.

  13A to 13E, the photothermal conversion layer 104 and the color ink layer 105 are shown as being formed on the ink receiving layer 103 for easy understanding. More precisely, however, the color ink and the black ink are absorbed in the ink receiving layer 103 and thus formed in the ink receiving layer 103.

  As described above, a color stereoscopic image is formed on the thermally expandable sheet 100 by expanding the portion of the thermally expandable sheet 100 where the light-to-heat conversion layers 104 and 106 are formed. The light-to-heat conversion layers 104 and 106 are heated more greatly as the concentration is higher, and thus expand more greatly. Therefore, it is possible to obtain stereoscopic images of various shapes by adjusting the shades of the photothermal conversion layers 104 and 106 according to the target height.

  In addition, you may abbreviate | omit either one of the process which heats the thermally expansible sheet 100 from the surface, and the process which heats from the back surface. For example, when only the surface of the thermally expandable sheet 100 is heated and expanded, steps S5 and S6 in FIG. 12 are omitted. On the other hand, when only the back surface of the thermally expandable sheet 100 is heated and expanded, steps S1 and S2 in FIG. 12 are omitted. The color image printing in step S3 may be executed after the process of heating the thermally expandable sheet 100 from the back side in step S6.

  When a monochrome stereoscopic image is formed, the printing apparatus 40 may print a monochrome image instead of a color image in step S3. In this case, a layer of black ink is formed on the ink receiving layer 103 and the photothermal conversion layer 104 instead of the color ink layer 105.

  Next, details of the processing executed by the expansion device 50 in steps S2 and S6 will be described with reference to the flowchart shown in FIG.

  In step S <b> 2, the user installs the thermally expandable sheet 100 on the tray 53 with the surface thereof facing upward and inserts it into the expansion device 50. Further, in step S <b> 6, the user installs the thermally expandable sheet 100 on the tray 53 with the back surface thereof facing up and inserts it into the expansion device 50. Thereafter, the user operates the operation unit 33 of the terminal device 30 and inputs an instruction to expand the thermally expandable sheet 100. When the control unit 71 of the expansion device 50 receives the instruction input from the user in this way from the terminal device 30, the control unit 71 starts the process illustrated in FIG.

  When the process is started, the control unit 71 determines whether or not the thermally expandable sheet 100 is correctly installed (step S11). More specifically, the control unit 71 determines whether or not the thermally expandable sheet 100 is installed at an appropriate position on the tray 53 via a sensor provided on the tray 53.

  When the thermally expandable sheet 100 is not correctly installed (step S11; NO), the control unit 71 stops the process at step S11. At this time, the control unit 71 issues a warning to notify the user that the thermally expandable sheet 100 is not correctly installed, and requests the user to correctly install the thermally expandable sheet 100.

  When the thermally expansible sheet 100 is correctly installed (step S11; YES), whether or not the control unit 71 has been able to read the barcode B attached to the back surface of the thermally expandable sheet 100 via the barcode reader 65. Is determined (step S12). The bar code B is an identifier for determining whether or not the heat-expandable sheet 100 can be used, and is provided at the end on the far side of the heat-expandable sheet 100 installed on the tray 53.

  When the barcode B attached to the thermally expandable sheet 100 cannot be read (step S12; NO), the control unit 71 returns the process to step S11. At this time, the control unit 71 notifies the user that the thermally expandable sheet 100 cannot be used, and requests the user to replace the thermally expandable sheet 100 with an appropriate one.

  When the barcode B can be read (step S12; YES), the control unit 71 performs preheating (preheating) (step S13). The pre-heat treatment is a process for preliminarily heating the irradiation unit 60 and the thermally expandable sheet 100 before the expansion device 50 starts the expansion process, which is a main operation. Before the thermal expansion sheet 100 is expanded, the expansion processing unit 81 performs preheat treatment for preheating by irradiating the irradiation unit 60 with light. Details of the pre-heat treatment will be described with reference to a flowchart shown in FIG.

  When the preheat treatment shown in FIG. 15 is started, the controller 71 turns on the lamp heater 61 (step S21). Specifically, the control unit 71 turns on the lamp heater 61 and heats the irradiation unit 60 in advance so that the expansion process can be performed smoothly. At this time, the control unit 71 drives the conveyance motor 55 as necessary, and reciprocates the irradiation unit 60 between the first position P1 and the second position P2, so that the entire thermally expandable sheet 100 is moved. Warm up evenly. Thereby, it is suppressed that the thermally expansible sheet 100 is heated locally in an expansion process.

  When the lamp heater 61 is turned on, the temperature of the reflector 62 irradiated with light from the lamp heater 61 starts to rise. At this time, the controller 71 measures the rate of temperature rise of the reflector 62 (step S22). Specifically, the temperature sensor 63 measures the temperature of the reflector 62 during the pre-heat treatment. The control unit 71 refers to the temperature measured by the temperature sensor 63 and obtains an increase value of the temperature of the reflecting plate 62 during a specified time after the lamp heater 61 is turned on. Step S22 is an example of a measurement step.

  When the temperature increase rate of the reflecting plate 62 is measured, the control unit 71 determines whether or not the temperature of the reflecting plate 62 has increased to a predetermined temperature (step S23). The predetermined temperature is an upper limit temperature in the preheat treatment, and is set to a temperature (for example, 70 ° C.) lower than a specified expansion temperature so that the thermally expandable sheet 100 does not start expansion in the preheat treatment. When the temperature of the reflecting plate 62 has not risen to the predetermined temperature (step S23; NO), the control unit 71 remains in step S23 and waits until the temperature of the reflecting plate 62 rises to the predetermined temperature.

  Finally, when the temperature of the reflecting plate 62 rises to a predetermined temperature (step S23; YES), the controller 71 turns off the lamp heater 61 (step S24). Thereafter, the control unit 71 drives the cooling unit 64 to cool the irradiation unit 60 as necessary, and reduces the temperature of the reflecting plate 62 to 40 ° C., for example.

  When the lamp heater 61 is turned off, the control unit 71 determines the moving speed of the irradiation unit 60 according to the temperature increase rate of the reflector 62 measured in step S22 (step S25). More specifically, the controller 71 estimates that the light energy emitted from the lamp heater 61 is relatively large when the temperature increase rate of the reflector 62 is relatively high. The moving speed of 60 is determined as a relatively high speed to shorten the irradiation time. On the other hand, the controller 71 estimates that the light energy emitted from the lamp heater 61 is relatively small when the temperature increase rate of the reflector 62 is relatively low. The moving speed is determined to be a relatively low speed to increase the irradiation time. In step S <b> 25, the control unit 71 functions as the speed determination unit 82. Step S25 is an example of a speed determination step. Thus, the preheat treatment shown in FIG. 15 is completed.

  Note that the control unit 71 may perform the pre-heat treatment shown in FIG. 15 every time the expansion device 50 performs the expansion process, or immediately after the power is supplied to the expansion device 50 or the expansion device 50. May be executed only when the expansion process has not been executed for a predetermined time or more.

  Returning to the flowchart shown in FIG. After performing the pre-heat treatment, the control unit 71 performs an expansion process (step S14). Specifically, the control unit 71 turns on the lamp heater 61 and causes the irradiation unit 60 to emit light. And the control part 71 moves the irradiation part 60 which is irradiating light from the 1st position P1 toward the 2nd position P2 by driving the conveyance motor 55, as shown in FIG. Let At this time, the control unit 71 moves the irradiation unit 60 at the moving speed determined in step S25. Accordingly, the control unit 71 expands the thermally expandable sheet 100 by heating the portion of the thermally expandable sheet 100 on which the grayscale image is printed to a specified temperature or higher. In step S <b> 14, the control unit 71 functions as the expansion processing unit 81. Step S14 is an example of an expansion step.

  As described above, the expansion device 50 according to Embodiment 1 determines the moving speed of the irradiation unit 60 according to the temperature increase speed of the reflector 62, and moves the irradiation unit 60 while moving the irradiation unit 60 at the determined moving speed. The thermally expandable sheet 100 is expanded by irradiating 60 with light. By using the temperature increase rate of the reflecting plate 62, the intensity of the light emitted from the irradiation unit 60 can be accurately estimated, so that the variation in the intensity of the light emitted from the irradiation unit 60 is canceled out. The moving speed of the irradiation unit 60 can be adjusted. Therefore, for example, even if the intensity of light emitted from the irradiation unit 60 varies due to fluctuations in the power supply voltage supplied to the irradiation unit 60, the thermally expandable sheet 100 can be expanded with high accuracy.

  In general, as a method of stabilizing the power supply voltage, a method of interposing a stabilized power supply and a method of detecting the fluctuation of the power supply voltage and controlling the power supplied to the irradiation unit 60 are known. However, any of the methods based on the slidac method, tap switching method, phase control method, etc., which are known as methods for interposing a stabilized power supply, lead to an increase in size and cost of the device. In addition, in order to detect fluctuations in the power supply voltage, there is a problem of detection accuracy due to conversion to low voltage and A / D (Analog / Digital) conversion, and further measures such as noise removal are required. This leads to an increase in size and cost.

  Even if the power supply voltage supplied to the irradiation unit 60 is stabilized, the intensity of light emitted from the irradiation unit 60 is also affected by factors such as individual differences of the lamp heater 61 and deterioration of the performance of the lamp heater 61. fluctuate. In the first place, it is difficult to detect and eliminate fluctuations caused by such factors.

  According to the expansion device 50 according to the first embodiment, the power supply voltage fluctuation, the lamp heater 61 can be achieved by a simple configuration of measuring the temperature of the reflector 62 and a simple method of adjusting the moving speed of the irradiation unit 60. Thus, the expansion process of the thermally expandable sheet 100 can be executed in consideration of the individual difference and the deterioration of the performance of the lamp heater 61. In particular, measuring the temperature of the reflector 62 is originally necessary for the irradiation unit 60 to perform a normal irradiation operation. Therefore, the expansion device 50 according to Embodiment 1 can accurately inflate the thermally expandable sheet 100 with a simple configuration without adding a configuration.

(Embodiment 2)
Next, Embodiment 2 of the present invention will be described. In the second embodiment, the description of the same configuration as that of the first embodiment is omitted.

  The expansion device 50 according to the first embodiment causes the irradiation unit 60 to irradiate light while moving the irradiation unit 60 along the front surface or the back surface of the thermally expandable sheet 100 fixed to the tray 53. The sheet 100 was expanded. On the other hand, the expansion device 150 according to the second embodiment expands the thermally expandable sheet 100 by irradiating light to the irradiation unit 60 fixed at a specific position while moving the thermally expandable sheet 100. Let

  FIG. 16 shows a configuration of the expansion device 150 according to the second embodiment. As shown in FIG. 16, the expansion device 150 includes a casing 151, a carry-in unit 152, a discharge unit 153, conveyance roller pairs 156 and 157, conveyance guides 158 and 159, an irradiation unit 160, and a barcode reader. 165, a reflector 166, and a control board 170.

  The carry-in unit 152 is a mechanism for carrying in the thermally expandable sheet 100. When the user expands the surface of the thermally expandable sheet 100 by irradiating light, the user sets the thermally expandable sheet 100 in the carry-in unit 152 with the surface facing upward. In addition, when the user irradiates the back surface of the thermally expandable sheet 100 with light and expands it, the user sets the thermally expandable sheet 100 in the carry-in unit 152 with the back surface facing upward. The thermally expandable sheet 100 installed in the carry-in unit 152 is conveyed into the housing 151 by the conveyance roller pairs 156 and 157 while being guided by the conveyance guides 158 and 159.

  The barcode reader 165 functions as a reading unit that reads the barcode B attached to the back surface of the thermally expandable sheet 100. The reflector 166 is a mirror that reflects light, and is disposed on the opposite side of the barcode reader 165 across the conveyance path of the thermally expandable sheet 100. The barcode reader 165 reads the barcode B attached to the back surface of the thermally expandable sheet 100 via the reflector 166 when the thermally expandable sheet 100 is set in the carry-in unit 152 with the front surface facing upward. On the other hand, when the thermally expandable sheet 100 is set in the carry-in unit 152 with the back surface facing upward, the barcode reader 165 converts the barcode B attached to the back surface of the thermally expandable sheet 100 into the reflector 166. Read directly without going through.

  The expansion device 150 determines whether the medium set in the carry-in unit 152 can be used by the expansion device 150 according to whether the barcode B can be read by the barcode reader 165. When the barcode B attached to the thermally expandable sheet 100 can be read by the barcode reader 165, the expansion device 150 carries the thermally expandable sheet 100 into the housing 151. On the other hand, when the barcode B attached to the thermally expandable sheet 100 cannot be read by the barcode reader 165, the expander 150 does not carry the thermally expandable sheet 100 into the housing 151. . Thereby, malfunction of expansion device 150 is controlled.

  The conveyance roller pairs 156 and 157 sandwich the thermally expandable sheet 100 carried in by the carry-in unit 152 and convey it along the conveyance guides 158 and 159. As shown in FIG. 17, the conveyance roller pairs 156 and 157 are connected to the conveyance motor 155 via at least one roller gear. The transport motor 155 is, for example, a stepping motor that operates in synchronization with pulse power. The transport roller pairs 156 and 157 rotate using the driving force accompanying the rotation of the transport motor 155 as a power source, and transport the thermally expandable sheet 100 with its front or back surface directed toward the irradiation unit 160.

  The thermally expandable sheet 100 receives light irradiated by the irradiation unit 160 while being transported by the transport roller pairs 156 and 157. As a result, the portion of the thermally expandable sheet 100 where the light-to-heat conversion layers 104 and 106 are printed is overheated and expanded. The thermally expandable sheet 100 thus expanded by being heated is discharged from the discharge unit 153. The conveyance roller pairs 156 and 157 function as moving means for relatively moving the thermally expandable sheet 100 and the irradiation unit 160 by cooperating with the conveyance motor 155.

  The irradiation unit 160 is a mechanism that irradiates light, and functions as an irradiation unit that irradiates light to the thermally expandable sheet 100 conveyed by the conveyance roller pairs 156 and 157. As shown in FIG. 17, the irradiation unit 160 includes a lamp heater 161, a reflection plate 162, a temperature sensor 163, and a cooling unit 164. Since these are the same as the lamp heater 61, the reflecting plate 62, the temperature sensor 63, and the cooling unit 64 in the first embodiment, description thereof is omitted. In other words, the irradiation unit 160 has the same configuration and function as the irradiation unit 60 in the first embodiment. However, the irradiation unit 160 is fixed at a specific position and does not move like the irradiation unit 60 in the first embodiment.

  Similar to the control board 70 in the first embodiment, the control board 170 includes a control unit 71, a storage unit 72, a time measuring unit 73, and a communication unit 74. The control unit 71 includes a CPU, a ROM, a RAM, and the like, and functions as an expansion processing unit 81 and a speed determination unit 82, respectively.

  The expansion processing unit 81 expands the thermally expandable sheet 100 by irradiating the irradiation unit 160 with light while moving the thermally expandable sheet 100 by the conveying roller pairs 156 and 157. More specifically, the expansion processing unit 81 supplies a power supply voltage to the irradiation unit 160 to turn on the lamp heater 161 in response to the thermal expansion sheet 100 being carried in from the carry-in unit 152. Then, the expansion processing unit 81 drives the conveyance motor 155 in a state where the irradiation unit 160 is irradiated with light, thereby causing the pair of conveyance rollers 156 and 157 to convey the thermally expandable sheet 100. Thereby, light is irradiated over the whole surface or the back surface of the thermally expandable sheet 100.

  The speed determination unit 82 determines the moving speed (conveying speed) of the thermally expandable sheet 100 conveyed by the conveying roller pairs 156 and 157 based on the temperature of the reflecting plate 162 measured by the temperature sensor 163. The method for determining the moving speed of the thermally expandable sheet 100 by the speed determining unit 82 is the same as the method for determining the moving speed of the irradiation unit 60 in the first embodiment.

  More specifically, as the moving speed of the thermally expandable sheet 100 increases, the irradiation time by the irradiation unit 160 is shortened, so that the amount of light irradiated to each part of the thermally expandable sheet 100 decreases. On the other hand, since the irradiation time becomes longer as the moving speed of the thermally expandable sheet 100 becomes lower, the amount of light irradiated on each part of the thermally expandable sheet 100 increases. Based on such a relationship, the speed determination unit 82 determines the moving speed of the thermally expandable sheet 100 so as to cancel the fluctuation in the intensity of light irradiated from the irradiation unit 160.

  The speed determination unit 82 acquires a rise value of the temperature measured by the temperature sensor 163 during a specified time as the temperature rise speed of the reflector 162 during the pre-heat treatment. And the speed determination part 82 determines the moving speed of the thermally expansible sheet 100 according to the acquired raise value. More specifically, the speed determination unit 82 is more likely to have a second increase value that is higher than the first value than a first value increase in the temperature of the reflector 162. The moving speed of the thermally expandable sheet 100 is determined to be a high speed.

  The expansion processing unit 81 irradiates the irradiation unit 160 with light while moving the thermally expandable sheet 100 by the conveying roller pairs 156 and 157 at the moving speed determined by the speed determining unit 82, thereby causing the thermally expandable sheet to be irradiated. 100 is inflated. As described above, the moving speed of the thermally expandable sheet 100 is adjusted so as to cancel the fluctuation in the intensity of light emitted from the irradiation unit 160. Therefore, even if the power supply voltage fluctuates, the thermally expandable sheet 100 can be expanded to a desired height, and a stereoscopic image can be formed on the thermally expandable sheet 100 with high accuracy.

  As described above, the expansion device 150 according to Embodiment 2 determines the moving speed of the thermally expandable sheet 100 according to the temperature increase speed of the reflector 162, and moves the thermally expandable sheet 100 at the determined moving speed. The thermally expandable sheet 100 is expanded by irradiating the irradiation unit 160 with light. Since the intensity of light emitted from the irradiation unit 160 can be accurately estimated by using the temperature increase rate of the reflector 162, the variation in the intensity of light emitted from the irradiation unit 160 is canceled out. The moving speed of the thermally expandable sheet 100 can be adjusted. Therefore, for example, even if the intensity of light emitted from the irradiation unit 160 varies due to a change in power supply voltage supplied to the irradiation unit 160, the thermally expandable sheet 100 can be expanded with high accuracy.

  Thus, if the thermally expandable sheet 100 and the irradiation units 60 and 160 can be moved relative to each other, the embodiment of the expansion device 150 that moves the thermally expandable sheet 100 as in the second embodiment is also used. 1, the thermally expandable sheet 100 can be expanded with high accuracy.

(Modification)
Although the embodiment of the present invention has been described above, the above embodiment is an example, and the scope of application of the present invention is not limited to this. That is, the embodiments of the present invention can be applied in various ways, and all the embodiments are included in the scope of the present invention.

  For example, in the above-described embodiment, the speed determination unit 82 determines the relative moving speed of the thermally expandable sheet 100 and the irradiation unit 60 according to the temperature increase rate measured by the temperature sensor 63. However, in the present invention, the speed determining unit 82 may determine the moving speed according to the rising time required for the temperature measured by the temperature sensor 63 to rise by the specified temperature.

  When the moving speed of the irradiation unit 60 is determined according to the temperature rise time measured by the temperature sensor 63, the speed determination unit 82 determines the temperature of the reflector 62 by the function of the time measuring unit 73 during the pre-heat treatment. The rise time required to rise from the first temperature (eg 40 ° C.) to the second temperature (eg 70 ° C.) is measured. And the speed determination part 82 acquires the temperature increase rate of the reflecting plate 62 according to the increase time. Contrary to the rate of temperature rise, this rise time becomes shorter when the light energy emitted from the irradiation unit 60 becomes relatively larger, and becomes longer when the light energy emitted from the irradiation unit 60 becomes relatively smaller. Become. Therefore, the speed determination unit 82 determines the movement speed to be a lower speed when the rising time is the second time longer than the first time than when the rising time is the first time. In other words, the speed determining unit 82 determines the moving speed to be a lower speed when the rising time is longer. About another structure, it is the same as that of the case where an ascending speed is used.

  Moreover, in the said embodiment, the temperature sensor 63 measured the temperature of the reflecting plate 62 as a to-be-irradiated body which receives the light irradiated from the irradiation part 60. FIG. However, in the case of an irradiated object that receives light emitted from the irradiation unit 60, the intensity of the light emitted from the irradiation unit 60 is estimated by measuring the temperature of the object, not the reflector 62. Can do. Therefore, in the present invention, the temperature sensor 63 may measure the temperature of an object other than the reflector 62. Moreover, the temperature sensor 63 may measure the temperature of the predetermined position in the expansion | swelling apparatus 50 not only to a to-be-irradiated body.

  In the above embodiment, the thermally expandable sheet 100 includes the base material 101, the thermally expandable layer 102, and the ink receiving layer 103. However, in the present invention, the configuration of the thermally expandable sheet 100 is not limited to this. For example, the thermally expandable sheet 100 may not include the ink receiving layer 103. Alternatively, the thermally expandable sheet 100 may include a layer made of any other material between the base material 101 and the thermally expandable layer 102 or between the thermally expandable layer 102 and the ink receiving layer 103. .

  In the above embodiment, the terminal device 30, the printing device 40, and the expansion devices 50 and 150 are independent devices. However, in the present invention, at least any two of the terminal device 30, the printing device 40, and the expansion devices 50 and 150 may be integrated.

  The printing method of the printing apparatus 40 is not limited to the ink jet method. For example, the printing apparatus 40 is a laser printer, and may print an image with toner and developer. The photothermal conversion layers 104 and 106 may be formed of a material other than black ink containing carbon black as long as it is a material that easily converts light into heat. In this case, the photothermal conversion layers 104 and 106 may be formed by means other than the printing device 40.

  In the above-described embodiment, the control unit 71 of the expansion devices 50 and 150 includes a CPU, and functions as the expansion processing unit 81 and the speed determination unit 82 by the function of the CPU. However, in the expansion devices 50 and 150 according to the present invention, the control unit 71 is, for example, an ASIC (Application Specific Integrated Circuit), an FPGA (Field-Programmable Gate Array), or a dedicated control circuit such as various control circuits instead of the CPU. Hardware may be provided, and dedicated hardware may function as each of the expansion processing unit 81 and the speed determination unit 82. In this case, each process may be executed by individual hardware, or each process may be collectively executed by a single hardware. In addition, a part of each process may be executed by dedicated hardware, and the other part may be executed by software or firmware.

  It should be noted that not only can the configuration for realizing the functions according to the present invention be provided in advance as an expansion device, but also the computer that controls the expansion device by application of the program is applied to the expansion devices 50 and 150 exemplified in the above embodiment. Each functional configuration can also be realized. That is, a program for realizing each functional configuration by the expansion devices 50 and 150 exemplified in the above embodiment can be applied so that a CPU or the like that controls an existing information processing apparatus or the like can be executed.

  The application method of such a program is arbitrary. The program can be applied by being stored in a computer-readable storage medium such as a flexible disk, a CD (Compact Disc) -ROM, a DVD (Digital Versatile Disc) -ROM, or a memory card. Furthermore, the program can be superimposed on a carrier wave and applied via a communication medium such as the Internet. For example, the program may be posted on a bulletin board (BBS: Bulletin Board System) on a communication network and distributed. The program may be started and executed in the same manner as other application programs under the control of an OS (Operating System) so that the above-described processing can be executed.

The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the specific embodiments, and the present invention includes the invention described in the claims and the equivalent scope thereof. included. Hereinafter, the invention described in the scope of claims of the present application will be appended.
(Appendix 1)
An irradiation means for irradiating the thermally expandable sheet with light;
Moving means for relatively moving the thermally expandable sheet and the irradiation means;
When the irradiation means preliminarily irradiates light prior to irradiating the thermally expansible sheet, the temperature increase rate at a predetermined position is determined based on the light irradiated from the irradiation means. Acquisition means for acquiring;
Setting means for setting a relative moving speed of the thermally expandable sheet and the irradiation means by the moving means based on the rising speed of the temperature acquired by the acquiring means;
Control means for irradiating the irradiation means with light while relatively moving the thermally expandable sheet and the irradiation means by the moving means at the moving speed set by the setting means;
An inflating device comprising:
(Appendix 2)
The acquisition means acquires the rising speed of the temperature at the predetermined position according to the rising temperature during a specified time at the predetermined position.
The expansion device according to Supplementary Note 1, wherein
(Appendix 3)
The acquisition means acquires the increase rate of the temperature at the predetermined position according to the increase time required to increase by a specified temperature at the predetermined position.
The expansion device according to Supplementary Note 1, wherein
(Appendix 4)
The setting means sets the moving speed to a higher speed when the rising speed of the temperature acquired by the acquiring means is larger.
The expansion device according to any one of appendices 1 to 3, characterized in that:
(Appendix 5)
The moving means moves the irradiation means along the front or back surface of the thermally expandable sheet,
The setting means sets a moving speed of the irradiation means by the moving means based on the rising speed of the temperature acquired by the acquiring means,
The control means causes the irradiation means to emit light while moving the irradiation means by the moving means at the moving speed set by the setting means.
The expansion device according to any one of appendices 1 to 4, characterized in that:
(Appendix 6)
The moving means moves the thermally expandable sheet,
The setting means sets the moving speed of the thermally expandable sheet by the moving means based on the rising speed of the temperature acquired by the acquiring means,
The control means causes the irradiation means to irradiate light while moving the thermally expandable sheet by the moving means at the moving speed set by the setting means.
The expansion device according to any one of appendices 1 to 4, characterized in that:
(Appendix 7)
The control means performs a preheat treatment to preheat the irradiation means before expanding the thermally expandable sheet,
The acquisition means acquires the rate of increase in temperature at the predetermined position during the pre-heat treatment.
The expansion device according to any one of appendices 1 to 6, characterized in that:
(Appendix 8)
An irradiated body that receives light emitted from the irradiation means;
The acquisition means includes
Obtaining the temperature increase rate of the irradiated object;
The expansion device according to any one of appendices 1 to 7, characterized in that:
(Appendix 9)
The irradiated body is a reflector that reflects the light irradiated from the irradiation unit toward the thermally expandable sheet.
The expansion device according to appendix 8, which is characterized in that.
(Appendix 10)
The expansion device according to any one of appendices 1 to 9,
A printing device that prints a light-to-heat conversion layer that converts light irradiated from the irradiation unit into heat on the front or back surface of the thermally expandable sheet;
The control means irradiates the irradiating means with light while relatively moving the thermally expansible sheet on which the photothermal conversion layer is printed by the printing apparatus and the irradiating means. Expanding a portion of the sheet on which the light-to-heat conversion layer is printed,
A three-dimensional image forming system.
(Appendix 11)
A thermal expansion sheet expansion method performed by an expansion device,
When the irradiation unit preliminarily irradiates light before irradiating the thermally expandable sheet, the temperature increase rate at a predetermined position is acquired based on the light irradiated from the irradiation unit. An acquisition step to
A setting step for setting a relative moving speed between the thermally expandable sheet and the irradiation unit based on the rising speed of the temperature acquired by the acquiring step;
A control step of irradiating the irradiation unit with light while relatively moving the thermally expandable sheet and the irradiation unit at the moving speed set in the setting step;
A method of expanding a thermally expandable sheet, comprising:
(Appendix 12)
Computer
Moving means for relatively moving the heat-expandable sheet and the irradiating part for irradiating light;
When the irradiation unit preliminarily irradiates light prior to irradiating the thermally expansible sheet, the temperature increase rate at a predetermined position is determined based on the light irradiated from the irradiation unit. Acquisition means to acquire,
Setting means for setting a relative moving speed of the thermally expandable sheet and the irradiation unit by the moving means based on the rising speed of the temperature acquired by the acquiring means;
Control means for irradiating light to the irradiating section while relatively moving the thermally expandable sheet and the irradiating section by the moving means at the moving speed set by the setting means;
Program to function as.

DESCRIPTION OF SYMBOLS 1 ... Three-dimensional image formation system, 30 ... Terminal device, 31 ... Control part, 32 ... Memory | storage part, 33 ... Operation part, 34 ... Display part, 35 ... Recording medium drive part, 36 ... Communication part, 40 ... Printing apparatus, 41 ... Carriage, 42 ... Print head, 43, 43k, 43c, 43m, 43y ... Ink cartridge, 44 ... Guide rail, 45 ... Drive belt, 45m ... Motor, 46 ... Flexible communication cable, 47 ... Frame, 48 ... Platen, 49a Paper feed roller pair, 49b ... Paper discharge roller pair, 50, 150 ... Expansion device, 51, 151 ... Housing, 52 ... Insertion part, 53 ... Tray, 54 ... Ventilation part, 55, 155 ... Conveyance motor, 56 ... Transport rail, 60, 160 ... irradiation unit, 61, 161 ... lamp heater, 62, 162 ... reflector, 63, 163 ... temperature sensor, 64, 164 ... cooling unit, 65, 16 DESCRIPTION OF SYMBOLS ... Barcode reader, 69 ... Power supply board, 70, 170 ... Control board, 71 ... Control part, 72 ... Memory | storage part, 73 ... Timing part, 74 ... Communication part, 81 ... Expansion processing part, 82 ... Speed determination part, 100 DESCRIPTION OF SYMBOLS ... Thermal expansion sheet, 101 ... Base material, 102 ... Thermal expansion layer, 103 ... Ink receiving layer, 104, 106 ... Photothermal conversion layer, 105 ... Color ink layer, 152 ... Carry-in part, 153 ... Discharge part, 156, 157 ... Conveying roller pair, 158, 159 ... Conveying guide, 166 ... Reflector, B ... Bar code, D1 ... Sub-scanning direction, D2 ... Main scanning direction

Claims (12)

An irradiation means for irradiating the thermally expandable sheet with light;
Moving means for relatively moving the thermally expandable sheet and the irradiation means;
When the irradiation means preliminarily irradiates light prior to irradiating the thermally expansible sheet, the temperature increase rate at a predetermined position is determined based on the light irradiated from the irradiation means. Acquisition means for acquiring;
Setting means for setting a relative moving speed of the thermally expandable sheet and the irradiation means by the moving means based on the rising speed of the temperature acquired by the acquiring means;
Control means for irradiating the irradiation means with light while relatively moving the thermally expandable sheet and the irradiation means by the moving means at the moving speed set by the setting means;
An inflating device comprising: The acquisition means acquires the rising speed of the temperature at the predetermined position according to the rising temperature during a specified time at the predetermined position.
The expansion device according to claim 1. The acquisition means acquires the increase rate of the temperature at the predetermined position according to the increase time required to increase by a specified temperature at the predetermined position.
The expansion device according to claim 1. The setting means sets the moving speed to a higher speed when the rising speed of the temperature acquired by the acquiring means is larger.
The expansion device according to any one of claims 1 to 3, wherein The moving means moves the irradiation means along the front or back surface of the thermally expandable sheet,
The setting means sets a moving speed of the irradiation means by the moving means based on the rising speed of the temperature acquired by the acquiring means,
The control means causes the irradiation means to emit light while moving the irradiation means by the moving means at the moving speed set by the setting means.
The expansion device according to any one of claims 1 to 4, wherein The moving means moves the thermally expandable sheet,
The setting means sets the moving speed of the thermally expandable sheet by the moving means based on the rising speed of the temperature acquired by the acquiring means,
The control means causes the irradiation means to irradiate light while moving the thermally expandable sheet by the moving means at the moving speed set by the setting means.
The expansion device according to any one of claims 1 to 4, wherein The control means performs a preheat treatment to preheat the irradiation means before expanding the thermally expandable sheet,
The acquisition means acquires the rate of increase in temperature at the predetermined position during the pre-heat treatment.
The expansion device according to any one of claims 1 to 6, wherein An irradiated body that receives light emitted from the irradiation means;
The acquisition means includes
Obtaining the temperature increase rate of the irradiated object;
The expansion device according to any one of claims 1 to 7, characterized in that. The irradiated body is a reflector that reflects the light irradiated from the irradiation unit toward the thermally expandable sheet.
The expansion device according to claim 8. An inflator according to any one of claims 1 to 9,
A printing device that prints a light-to-heat conversion layer that converts light irradiated from the irradiation unit into heat on the front or back surface of the thermally expandable sheet;
The control means irradiates the irradiating means with light while relatively moving the thermally expansible sheet on which the photothermal conversion layer is printed by the printing apparatus and the irradiating means. Expanding a portion of the sheet on which the light-to-heat conversion layer is printed,
A three-dimensional image forming system. A thermal expansion sheet expansion method performed by an expansion device,
When the irradiation unit preliminarily irradiates light before irradiating the thermally expandable sheet, the temperature increase rate at a predetermined position is acquired based on the light irradiated from the irradiation unit. An acquisition step to
A setting step for setting a relative moving speed between the thermally expandable sheet and the irradiation unit based on the rising speed of the temperature acquired by the acquiring step;
A control step of irradiating the irradiation unit with light while relatively moving the thermally expandable sheet and the irradiation unit at the moving speed set in the setting step;
A method of expanding a thermally expandable sheet, comprising: Computer
Moving means for relatively moving the heat-expandable sheet and the irradiating part for irradiating light;
When the irradiation unit preliminarily irradiates light prior to irradiating the thermally expansible sheet, the temperature increase rate at a predetermined position is determined based on the light irradiated from the irradiation unit. Acquisition means to acquire,
Setting means for setting a relative moving speed of the thermally expandable sheet and the irradiation unit by the moving means based on the rising speed of the temperature acquired by the acquiring means;
Control means for irradiating light to the irradiating section while relatively moving the thermally expandable sheet and the irradiating section by the moving means at the moving speed set by the setting means;
Program to function as.

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