EP3978672A1 - Stickvorrichtung, färbende stickvorrichtung und färbendes sticksystem - Google Patents

Stickvorrichtung, färbende stickvorrichtung und färbendes sticksystem Download PDF

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Publication number
EP3978672A1
EP3978672A1 EP21199735.8A EP21199735A EP3978672A1 EP 3978672 A1 EP3978672 A1 EP 3978672A1 EP 21199735 A EP21199735 A EP 21199735A EP 3978672 A1 EP3978672 A1 EP 3978672A1
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EP
European Patent Office
Prior art keywords
thread
embroidery
needle
color
dyeing
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP21199735.8A
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English (en)
French (fr)
Inventor
Kento AOKI
Yasunobu Takagi
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Ricoh Co Ltd
Original Assignee
Ricoh Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from JP2021131098A external-priority patent/JP2022058181A/ja
Application filed by Ricoh Co Ltd filed Critical Ricoh Co Ltd
Publication of EP3978672A1 publication Critical patent/EP3978672A1/de
Withdrawn legal-status Critical Current

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    • DTEXTILES; PAPER
    • D06TREATMENT OF TEXTILES OR THE LIKE; LAUNDERING; FLEXIBLE MATERIALS NOT OTHERWISE PROVIDED FOR
    • D06BTREATING TEXTILE MATERIALS USING LIQUIDS, GASES OR VAPOURS
    • D06B11/00Treatment of selected parts of textile materials, e.g. partial dyeing
    • D06B11/002Treatment of selected parts of textile materials, e.g. partial dyeing of moving yarns
    • D06B11/0023Treatment of selected parts of textile materials, e.g. partial dyeing of moving yarns by spraying or pouring
    • DTEXTILES; PAPER
    • D05SEWING; EMBROIDERING; TUFTING
    • D05BSEWING
    • D05B47/00Needle-thread tensioning devices; Applications of tensometers
    • D05B47/04Automatically-controlled tensioning devices
    • DTEXTILES; PAPER
    • D05SEWING; EMBROIDERING; TUFTING
    • D05BSEWING
    • D05B67/00Devices incorporated in sewing machines for lubricating, waxing, or colouring the threads
    • DTEXTILES; PAPER
    • D05SEWING; EMBROIDERING; TUFTING
    • D05CEMBROIDERING; TUFTING
    • D05C11/00Devices for guiding, feeding, handling, or treating the threads in embroidering machines; Machine needles; Operating or control mechanisms therefor
    • D05C11/08Thread-tensioning arrangements
    • DTEXTILES; PAPER
    • D05SEWING; EMBROIDERING; TUFTING
    • D05CEMBROIDERING; TUFTING
    • D05C11/00Devices for guiding, feeding, handling, or treating the threads in embroidering machines; Machine needles; Operating or control mechanisms therefor
    • D05C11/24Devices for guiding, feeding, handling, or treating the threads in embroidering machines; Machine needles; Operating or control mechanisms therefor incorporating devices for dyeing or impregnating the threads

Definitions

  • Embodiments of the present disclosure relate to an embroidery apparatus, a dyeing embroidery apparatus, and a dyeing embroidery system.
  • Japanese Unexamined Patent Application Publication No. 2008-289522 describes a technology for performing embroidery using a continuous upper thread whose color changes such that a color change point of the upper thread is not exposed on the surface of the embroidery.
  • embroidery data is created for performing embroidery such that the color change point of the upper thread whose color changes is not visible from the upper side.
  • the actual consumption speed of the upper thread is calculated from the state of progress of the embroidery by detecting the position of a needle in the embroidery apparatus, and the embroidery is adjusted according to a speed variation of the consumption of the upper thread occurring in the embroidery apparatus.
  • the upper thread may expand or contract during or after dyeing, or the tension balance between the upper thread and the lower thread may fluctuate to cause an error in the feed amount of the upper thread.
  • the position of the color change point of the upper thread may shift when the upper thread reaches the needle. If the embroidery is continued in this state, it is considered that a color change point of the upper thread is exposed to the upper surface side in the embroidery region on the cloth, or a color boundary position in the embroidery region is changed, so that an image of the embroidery pattern may be distorted.
  • an object of the present invention is to provide an embroidery apparatus that restrains the occurrence of the positional deviation of the color of a thread that is caused by the expansion and contraction of the thread occurring before the thread reaches the needle or the tension balance between the upper thread and the lower thread in stitches.
  • an embroidery apparatus includes an embroidery apparatus that includes a needle, a conveyance roller, a detector, and a roller controller.
  • the conveyance roller conveys a thread to be fed to the needle while pressing the thread.
  • the detector is disposed in a vicinity of the needle and configured to detect a color of the thread being embroidered.
  • the roller controller adjusts at least one of a pressure or a conveyance speed of the conveyance roller, based on a number of stitches indicating how many times the needle has been sewn on a cloth and the color of the thread detected by the detector.
  • a dyeing embroidery system in another aspect of the present invention, includes a dyeing apparatus to dye a thread with a color that changes and the embroidery apparatus.
  • the embroidery apparatus is disposed at a subsequent stage of the dyeing apparatus.
  • a dyeing embroidery apparatus includes a dyeing unit, a conveyance roller, an embroidery unit, and a roller controller.
  • the dyeing unit includes a dyeing device to dye a thread with a color that changes.
  • the conveyance roller conveys the thread dyed by the dyeing device and fed to a needle while pressing the thread.
  • the embroidery unit performs embroidery on a cloth using the thread fed from the conveyance roller.
  • the embroidery unit includes the needle and a detector. The detector is disposed in a vicinity of the needle to detect a color of the thread being embroidered.
  • the roller controller adjusts a pressure or a conveyance speed of the conveyance roller, based on a number of stitches indicating how many times the needle has been sewn on the cloth and the color of the thread detected by the detector.
  • a dyeing embroidery system includes a dyeing apparatus, an embroidery apparatus, and a roller controller.
  • the dyeing apparatus dyes a thread.
  • the embroidery apparatus performs embroidery on a cloth using the thread dyed by the dyeing apparatus.
  • the dyeing apparatus includes a dyeing device that dyes the thread with a color that changes and a conveyance roller to convey the thread dyed by the dyeing device while pressing the thread.
  • the embroidery apparatus includes a needle and a detector. The detector is disposed in a vicinity of the needle to detect a number of stitches indicating how many times the needle has been sewn on the cloth and the color of the thread being embroidered.
  • the roller controller adjusts a pressure or a conveyance speed of the conveyance roller, based on the number of stitches and the color of the thread detected by the detector.
  • the roller controller is disposed in the dyeing apparatus, the embroidery apparatus, or a higher-level control apparatus connected to the dyeing embroidery system.
  • the embroidery apparatus can restrain the occurrence of the positional deviation of the color of the thread that is caused by the expansion and contraction of the thread occurring before the thread reaches the needle and the tension balance between the upper thread and the lower thread in stitches.
  • FIG. 1 is a schematic view of an embroidery apparatus 1 according to a first embodiment of the present invention.
  • FIG. 2 is a schematic block diagram of the embroidery apparatus 1 according to the first embodiment of the present invention.
  • the embroidery apparatus 1 illustrated in FIG. 1 includes a needle 11, a lower-thread rotator 12, a stage 13, an upper-thread spool 14, a detector 17, nipping rollers 18, and an embroidery head 10.
  • an upper thread N is passed through a needle hole at the needle tip.
  • the needle 11 is vertically movable with respect to a cloth C.
  • the lower-thread rotator 12 includes a lower-thread bobbin 121 serving as a lower-thread supplier around which the lower thread B is wound and a hook 122.
  • the lower-thread bobbin 121 and the hook 122 rotate in conjunction with the movement of the needle 11.
  • the lower-thread rotator 12 also includes, for example, a cylindrical inner shuttle that accommodates the lower-thread bobbin 121, a bottomed cylindrical outer shuttle, and a cylindrical case integrated with the hook 122.
  • FIG. 1 illustrates an example in which the lower-thread bobbin 121 is of a vertical rotation type (a vertical full-rotary shuttle type or a vertical half-rotary shuttle type) in which the rotation direction is the vertical direction.
  • the lower-thread bobbin 121 may be of a horizontal rotation type (a horizontal shuttle type) in which the rotation direction is the horizontal direction.
  • the stage 13 is a table for holding the cloth C and has a hole 130 through which the needle 11 passes.
  • the stage 13 is movable in the X direction and the Y direction to feed the cloth C.
  • the width direction of the embroidery apparatus 1 is referred to as X
  • the depth direction of the embroidery apparatus 1 is referred to as Y
  • the height direction (vertical direction) of the embroidery apparatus 1 is referred to as Z.
  • the upper-thread spool 14 is an upper-thread supplier, around which the upper thread N is wound, to supply the needle thread N to the needle 11.
  • the upper thread N supplied from the upper-thread spool 14 is imparted in advance with a color that changes in the conveyance direction.
  • the detector 17 is a sensor for simultaneously detecting (1) the vertical movement of the needle 11 and (2) the color of the thread, and is disposed in the vicinity of the needle 11, for example, in the embroidery head 10.
  • the detector 17 detects the number of stitches corresponding to how many times the needle 11 has been raised and lowered or how many stitches have been advanced, and simultaneously detects the color of the thread at the position of the needle hole of the needle 11.
  • the detector 17 simultaneously detects the number of stitches and the color of the thread N at the position of the needle hole of the needle 11 at the needle drop timing at which the needle 11 sticks into the cloth C.
  • the nipping rollers 18 are conveyance rollers (pressing conveyance rollers) that convey the upper thread N supplied from the upper-thread spool 14 and fed to the needle 11 while applying pressure to the upper thread N.
  • other rollers such as a roller 101 may be provided as means for conveying the upper thread N.
  • the embroidery head 10 is provided with a needle vertical driving unit 193 that drives the needle 11 up and down and a computing mechanism 16 (see FIG. 2 ).
  • the embroidery head 10 controls the movement (handling) of the needle 11 through which the upper thread N passes and the movement of the stage 13, thereby performing embroidery on the cloth C using the upper thread N and the lower thread B that is fed in accordance with the feeding of the upper thread N.
  • examples of the "thread” including the upper thread and the lower thread include glass fiber thread; wool thread; cotton thread; synthetic fiber thread; metallic thread; mixed thread of wool, cotton, polymer, or metal; and linear object (linear member or continuous material) to which yarn, filament, or liquid is applied.
  • examples of the "thread” also include braided cord and flatly braided cord.
  • the embroidery apparatus 1 includes an embroidery-data creating unit 15, the computing mechanism 16, a driver 191, a drive motor 192, a needle vertical driving unit 193, a lower-thread rotation driving unit 194, an X-axis driving unit 195, and a Y-axis driving unit 196 that serve as a section related to drive control.
  • the detector 17, the driver 191, the drive motor 192, and the needle vertical driving unit 193 are built in the embroidery head 10 above the needle 11 or attached to the embroidery head 10.
  • the embroidery-data creating unit 15 and the computing mechanism 16 may also be built in the embroidery head 10.
  • the embroidery-data creating unit 15 acquires an embroidery image (embroidery file) from which the embroidery data is generated, creates the embroidery data based on the embroidery image, and outputs the embroidery data to the computing mechanism 16 and the driver 191.
  • an embroidery image (embroidery file) from which the embroidery data is generated
  • creates the embroidery data based on the embroidery image and outputs the embroidery data to the computing mechanism 16 and the driver 191.
  • the embroidery image is image data (image information or embroidery design data) serving as an original of an embroidery pattern on a cloth.
  • the embroidery-data creating unit 15 separates the embroidery image into colors (RGB values), sets the sewing order so as to realize the embroidery pattern on the cloth in consideration of the color positions of a thread that has been dyed in advance so as to change colors, and creates embroidery data for forming stitches on the cloth.
  • the embroidery data is data (paired data) obtained by combining data of coordinates at which the needle is moved and items to be executed at the coordinates (what is to be executed at each position).
  • the items to be executed at the coordinates include: (1) the needle is inserted into the cloth to catch the upper thread, the needle is returned to the surface of the cloth, and then the needle is moved to the next position to be inserted; (2) the embroidery is ended or interrupted (including switching to another needle and cutting the thread to move to a distant place where the embroidery is not continuous); and (3) the needle is moved to the initialization position (alignment position).
  • formats such as ".dst" and".pes" are generally known.
  • the computing mechanism 16 calculates the assumed consumption amount of the upper thread based on the embroidery data, and outputs a control signal for adjusting the pressing force or the conveyance speed of the nipping rollers 18 to a roller pressing unit 183 or a rotary motor 187 as necessary with reference to the progress state of how many stitches have been advanced, which is detected by the detector 17, and the color detection timing.
  • the roller pressing unit 183 adjusts the pressing force of the nipping rollers 18 to adjust the tension of the thread held in the nip.
  • the computing mechanism 16 adjusts the rotation speed of the rotary motor 187 to adjust the conveyance speed of the thread N by the nipping rollers 18.
  • the driver 191 drives and controls the drive motor 192 based on the embroidery data.
  • the needle vertical driving unit 193 is also referred to as a balance and converts the rotational movement of an upper shaft connected to the drive motor 192 into the vertical movement to drive the up-and-down movement of the needle 11 through which the upper thread N is passed.
  • the lower-thread rotation driving unit 194 rotates the lower-thread rotator 12 in conjunction with the vertical movement of the needle 11 by the rotational movement of a lower shaft connected to the upper shaft via, for example, a belt, a cam, and a crank.
  • the X-axis driving unit 195 and the Y-axis driving unit 196 are stage movement drive units serving as cloth feeders and drive the movement of the stage 13, on which the cloth C is placed, in the X direction and the Y direction in conjunction with the vertical movement of the needle 11 and the rotation of the lower-thread rotator 12 by the rotational movement of the lower shaft.
  • the cloth C may be fed by moving the entire stage 13 or by moving a feed dog provided on the hole 130 formed in the stage 13.
  • the needle vertical driving unit 193, the lower-thread rotation driving unit 194, the X-axis driving unit 195, and the Y-axis driving unit 196 serve as a drive mechanism that is driven in conjunction with one drive motor 192. Accordingly, the vertical movement of the needle 11, the rotational movement of the lower-thread rotator 12, and the X-and-Y movement of the cloth C on the stage 13 are generated by the rotation of the drive motor 192. For example, one vertical movement of the needle 11 is performed in conjunction with one or an integral number of rotational movements of the lower-thread rotator 12.
  • FIG. 3 is a schematic diagram illustrating an example of stitches on the upper side and the lower side of an upper thread and a lower thread with respect to a cloth.
  • Part (a) of FIG. 3 is a top view and part (b) of FIG. 3 is a bottom view.
  • FIG. 4 is a diagram illustrating the balance between the upper thread and the lower thread in stitches on the cloth.
  • part (a) illustrates a case where the tension balance between the upper thread and the lower thread is proper
  • part (b) illustrates a case where the tension of the upper thread is larger than the tension of the lower thread
  • part (c) illustrates a case where the tension of the upper thread is smaller than the tension of the lower thread.
  • the upper thread N is also drawn into the back side of the cloth C together with the needle 11. Thereafter, when the needle 11 rises, is pulled out from the cloth C, and returns to the front side of the cloth C, the upper thread N forms a loop on the back side of the cloth C due to the frictional force between the upper thread N and the cloth C, and remains on the back side of the cloth C. At this time, the hook 122 is caught by the loop-shaped upper thread N by the rotation of the lower-thread rotator 12, and the lower thread B passes through the loop of the upper thread N. Further, when the needle 11 is raised above the cloth C, the position where the upper thread N and the lower thread B cross each other is pulled up to the cloth C, thereby forming a stitch on the cloth C.
  • FIG. 3 is an enlarged view of stitches embroidered by pattern stitching (satin stitching) so as to fill the surface from top to bottom.
  • part (b) of FIG. 3 depicting the back side the catching portions between the upper thread N and the lower thread B surrounded by the dotted line is illustrated loosely for easy understanding of the relationship between the threads. However, actually, the upper thread N and the lower thread B are in contact with each other at the catching portions to pull each other.
  • FIG. 4 is a cross-sectional view of a region indicated by an alternate long and short dash line in FIG. 3 .
  • the cross section is as illustrated in part (a) of FIG. 4 .
  • the consumption speed of the upper thread N depends on the amount of the upper thread N that turns around to the back side of the cloth C. As illustrated in parts (b) and (c) of FIG. 4 , in a situation where the turnaround amount is different from the predicted amount, there is a large difference between the predicted amount of consumption of the upper thread and the cumulative amount of consumption of the thread accumulated while the embroidery is continued.
  • the consumption of a thread is set according to the color of the upper thread, or the dyeing of the upper thread is performed with respect to the predicted position of the thread consumption.
  • the amount of consumption of the upper thread up to the color change position is detected, and the tension of the upper thread or the conveyance speed of the upper thread is adjusted so as to reduce the difference from the predicted amount of consumption up to the color change position, thereby adjusting the amount of consumption of the upper thread.
  • the actual consumption amount of the upper thread based on the actually detected detection information and the estimated thread consumption amount predicted from the embroidery data are compared with each other while referring to information indicating how far the embroidery has advanced (coordinate position information calculated by the detector 17).
  • FIG. 5A is a diagram illustrating a detector according to an embodiment of the present invention.
  • FIG. 5B is a diagram illustrating a detector according to another embodiment of the present invention.
  • the embroidery head 10 and the lower-thread rotator 12 are omitted.
  • FIG. 5A illustrates an example of an integral-type detector 17 according to an embodiment of the present invention.
  • FIG. 5B illustrates a separate-type detector 17A according to another embodiment of the present invention.
  • the detector 17 illustrated in FIG. 5A is, for example, a color laser sensor.
  • a color laser sensor is a type of photoelectric sensor that emits light from a light projecting unit and detects light reflected by a detection object by a light receiving unit.
  • the color laser sensor can detect the amount of received light of each of red, blue, and green, thus allowing determination of the color of the object (the colors of the needle and the thread).
  • the detector 17 sets the needle drop position where the needle N sticks into the cloth C as the irradiation range of the object, and detects the time and color at the moment at which the needle 11 sticks into the cloth C.
  • the detector 17 can detect the number of stitches by counting the number of needle drops, and can simultaneously detect the color of the thread at the timing used for forming a stitch on the cloth.
  • the detector 17 constituted by one color laser sensor may be used only for color detection, and the number of stitches corresponding to the current position may be called from the driver 191 that drives based on the embroidery data.
  • the color laser sensor 171 may detect the color at the needle drop timing when the needle 11 sticks into the cloth C, and the number of stitches and the color of the thread may be associated with each other by the computing mechanism 16 in the subsequent stage.
  • the means for counting the number of stitches and the means for detecting the color of the thread are implemented by separate detection units.
  • the means for detecting the color of the thread is an optical sensor 171 such as a color laser sensor, which is a sensor capable of detecting at least the color of the thread, similarly to the detector 17.
  • a stitch sensor 172 is provided as means for counting the number of stitches (second detection unit).
  • the stitch sensor 172 is a sensor for detecting the vertical movement of the needle 11 and is provided, for example, on a needle bar that holds the needle 11.
  • the stitch sensor 172 detects the number of stitches corresponding to how many times the needle 11 has moved up and down, that is, how many stitches have been advanced by the needle 11.
  • the color laser sensor 171 detects the color at the needle drop timing at which the needle 11 sticks into the cloth C detected by the stitch sensor 172, so that the number of stitches and the color of the thread at the position of the needle hole of the needle can be simultaneously detected.
  • the color of the thread on the needle 11 used for embroidery in particular, the transition of the color of the thread can be grasped in real time without a temporal error during the embroidery operation.
  • FIGS. 6A and 6B are schematic diagrams illustrating adjustment of nipping rollers according to different embodiments of the present invention.
  • FIG. 6A is a schematic diagram illustrating nipping rollers 18 used in a first control example.
  • FIG. 6B is a schematic diagram illustrating nipping rollers 18A used in a second control example and a third control example.
  • the nipping rollers 18 are opposed rollers, including a pressing roller 181 and a roller 182, facing each other.
  • the pressing roller 181 is pressed by the roller pressing unit 183 to nip a thread N between the roller 182 and the pressing roller 181 while pressing the thread N, thereby forming a nip in a nipping region.
  • the pressing force P of the pressing roller 181 by the roller pressing unit 183 is adjusted based on the number of stitches and the position of the color of the thread detected by the detector 17.
  • the pressure of the nipping rollers 18, that is, the tension of the thread N held in the nip is adjusted.
  • the roller 182 illustrated in FIG. 6A is a driven roller to which no rotational driving force is applied.
  • the roller 182 may be a driving roller to which a rotational driving force is applied.
  • the conveyance speed is not adjusted according to the detection result of the detector 17.
  • the nipping rollers 18 capable of adjusting the tension and the detector 17 for simultaneously detecting the number of stitches and the position of the color of the thread can be combined in this manner to adjust the feed amount of the thread N from the nipping rollers 18 to the needle 11 in real time in accordance with the consumption amount of the thread.
  • the correction of the color shift of the thread N can be controlled before a large shift occurs.
  • the nipping rollers 18A are opposed rollers, including a pressing roller 184 and a drive roller 185, facing each other.
  • the pressing roller 184 is pressed by a roller pressing unit 186 to nip a thread N between the pressing roller 184 and the drive roller 185, thereby forming a nip in a nipping region.
  • the drive roller 185 is connected to the rotary motor 187 that transmits a rotational driving force.
  • the rotation speed of the drive roller 185 by the rotary motor 187 is adjusted based on the number of stitches and the position of the color of the thread by the detector 17, thereby adjusting the conveyance speed (also referred to as supply speed or speed) of the thread.
  • the conveyance speed also referred to as supply speed or speed
  • the pressing force P is fixed at a constant value during the embroidery operation, and the adjustment according to the detection result of the detector 17 is not performed.
  • the nipping rollers 18A capable of adjusting the conveyance speed and the detector 17 for simultaneously detecting the number of stitches and the position of the color of the thread can be combined in this manner to adjust the feed amount of the thread N from the nipping rollers 18 to the needle 11 in real time in accordance with the consumption amount of the thread.
  • the correction of the color shift of the thread N can be controlled before a large shift occurs.
  • control is performed by combining adjustment of the pressing force P of the pressing roller 181 by the roller pressing unit 183 and adjustment of the rotation speed of the drive roller 185 by the rotary motor 187 according to the case.
  • control methods for adjusting the nipping rollers for adjusting the color position of the thread there are three control methods for adjusting the nipping rollers for adjusting the color position of the thread.
  • the functional configuration of each control is described with reference to FIGS. 7 to 14 .
  • FIG. 7 is a functional block diagram of a control section of an embroidery apparatus according to the first control example.
  • Each of the embroidery-data creating unit 15 and the computing mechanism 16 is a control device and is implemented by an information processing device such as a central processing unit (CPU), an application specific integrated circuit (ASIC), or a field programmable gate array (FPGA).
  • CPU central processing unit
  • ASIC application specific integrated circuit
  • FPGA field programmable gate array
  • the computing mechanism 16 of the present control example includes a stitch-by-stitch thread-color prediction unit 601, an assumed-thread-consumption calculation unit 602, an embroidery-progress determination unit 603, an actual-thread-consumption calculation unit 604, a thread-consumption-progress calculation unit 605, a tension setting unit 606, and a correlation storage unit 607.
  • the stitch-by-stitch thread-color prediction unit 601 acquires the embroidery data from the embroidery-data creating unit 15, accumulates the movement distance in the coordinate data, from the coordinate data when the needle 11 moves relative to the cloth C and the number of stitches (the number of vertical movements) of the needle included in the embroidery data, and predicts the color of the thread used for embroidery located at the needle tip of the needle 11 at the needle drop timing of the stitch. That is, the thread color is predicted for each stitch (for each number of up-and-down movements of the needle). Then, in response to a call from the embroidery-progress determination unit 603, the thread color predicted in association with the number of stitches is output.
  • the assumed-thread-consumption calculation unit 602 serving as a thread-consumption estimation unit estimates the cumulative estimated needle thread consumption (consumption length) at the current stitch data point, based on the coordinate data of the needle 11 per stitch included in the embroidery data and the stitch data (data indicating how many stitches have been advanced) acquired from the embroidery-progress determination unit 603. That is, the assumed thread consumption amount associated with the stitch data is calculated.
  • the assumed consumption amount of the upper thread N increases when, for example, the distance between stitches is long and the embroidery in which the movement distance of the cloth C on the stage 13 is long continues.
  • the assumed consumption amount of the upper thread N decreases when the distance between stitches is short and the embroidery in which the movement distance of the cloth C on the stage 13 is short continues.
  • the embroidery-progress determination unit 603 acquires, in real time, stitch data (the number of stitches) that is data indicating how many stitches have been advanced, that is, which stitch is currently being sewn, output from the detector 17. Further, the embroidery-progress determination unit 603 acquires the color of the thread positioned at the needle tip of the needle 11 in the stitch in real time, which is output from the detector 17. Thus, the current embroidery position data (position in the embroidery data) indicating to what extent the embroidery has been advanced in the embroidery data is calculated.
  • the embroidery-progress determination unit 603 compares, in the stitches, the target thread color calculated from the embroidery data with the actual thread color detected by the detector 17 to calculate the current embroidery position in the embroidery data.
  • the actual-thread-consumption calculation unit 604 serving as a thread-consumption calculation unit calculates the actual consumption of the needle thread N, based on the current embroidery position in the embroidery data calculated by the embroidery-progress determination unit 603 and the actual thread color detection timing.
  • the upper thread and the lower thread are set so as to have a tension balance as illustrated in FIG. 4A at the start of embroidery, the upper thread may be stretched during conveyance from the upper-thread spool 14 to the needle 11. In such a case, the distance to the color change position of the upper thread set in advance becomes longer.
  • the upper thread passed through the needle may be strongly pulled in the embroidery operation due to, for example, a large amount of movement to the position where the needle is to be inserted or a large number of interruptions, and the tension of the upper thread may be large due to attraction between the upper thread and the lower thread. In such a case, as illustrated in FIG.
  • the amount of turnaround of the upper thread in stitches is reduced, and the amount of consumption of the upper thread is reduced. Accordingly, the distance to the color change position of the upper thread becomes longer. Therefore, in such a case, the detection timing until the actual color change is later than the detection timing until the assumed color change, and "the consumption length of the thread until the actual color change > the consumption length of the thread until the assumed color change" is satisfied.
  • the distance to the color change position of the upper thread N set in advance becomes shorter.
  • the tension of the upper thread passed through the needle is weak in the embroidery operation, and the tension of the upper thread is small in the attraction between the upper thread and the lower thread, as illustrated in FIG. 4C , the amount of turnaround of the upper thread in stitches increases and the amount of consumption of the upper thread increases. Accordingly, the distance to the color change position in the upper thread becomes short. Therefore, in such a case, the detection timing until the actual color change is earlier than the detection timing until the assumed color change, and "the consumption length of the thread until the actual color change ⁇ the consumption length of the thread until the assumed color change" is satisfied.
  • the thread-consumption-progress calculation unit 605 compares the thread consumption length until the actual color change with the thread consumption length until the assumed color change to determine whether the current embroidery is advanced or delayed with respect to the target thread consumption.
  • the tension setting unit 606 serving as a tension adjusting unit refers to the correlation data stored in the correlation storage unit 607, sets the corrected pressing force according to the difference (deviation amount) of the consumption amount, and outputs a control signal to the roller pressing unit 183, thereby adjusting the tension applying amount to the thread N in the nipping rollers 18, which is the pressure of the nipping rollers 18.
  • the consumption length of the thread until the actual color change > the consumption length of the thread until the assumed color change that is, when the actual upper thread is delayed, the region of the thread until the color change is extended, or the tension of the upper thread in the stitch is strong and the consumption amount of the upper thread is small due to the embroidery operation. For this reason, the pressing force at the nipping rollers 18 and the tension of the thread are weakened to increase the supply speed of the upper thread and the amount of turnaround (feed amount) of the upper thread at the stitches, thus increasing the consumption of the thread.
  • the consumption length of the thread until the actual color change ⁇ the consumption length of the thread until the assumed color change
  • the pressing force and the tension of the nipping rollers 18 are increased to reduce the supply speed of the upper thread.
  • the turnaround amount (feed amount) of the upper thread in the stitch is reduced to reduce the consumption of the thread.
  • Detecting and adjusting the tension in this manner allows the correction of the color shift to be controlled in real time without causing a time delay until the adjustment after the detection as much as possible.
  • the trigger of the tension adjustment in the present control example is the detection of the color change
  • the tension adjustment is performed, for example, at the timing immediately after the stitch in which the consumption length of the thread until the actual color change is longer than estimated and the color change is detected later than estimated.
  • the tension adjustment is performed at the timing immediately after the stitch at which the assumed consumption length estimated reaches the color change.
  • elements other than the embroidery-progress determination unit 603 serve as the roller controller 6, and have functions that can be provided on a higher-level control device in a third embodiment described later.
  • FIG. 8 is a flowchart of the first control example.
  • FIG. 9 illustrates an example of a correlation table for correcting the consumption amount of thread and the thread tension used in the first control example.
  • step S101 a tension of an initial value is set.
  • step S102 the computing mechanism 16 of the embroidery apparatus 1 reads embroidery data.
  • the dyeing device reads dyeing data at this timing.
  • step S103 the computing mechanism 16 calculates the expected consumption (assumed consumption amount) of the thread until the first color change.
  • the estimated thread consumption which is the expected cumulative thread consumption, is a cumulative amount of consumption of variable stitches.
  • the expected cumulative thread consumption amount is 0 mm up to stitch 1, 3 mm up to stitch 2, 5 mm up to stitch 3, 6 mm up to stitch 4, and 10 mm up to stitch 5.
  • the expected thread color values are red from 0 to 4 mm and blue from 5 to 10 mm, it is predicted that the first color change occurs in stitch 3 because the first color change in the embroidery data is at the position of 5 mm.
  • step S104 the embroidery operation is started. At this time, when one of the nipping rollers 18 is the roller 182 as a driving roller, the thread is fed to the embroidery position at a default feed speed.
  • step S105 When the detector 17 (or 17A) detects that the color of the thread at the embroidery position has changed in step S105, the actual consumption amount of the thread until the color change is calculated in step S106.
  • step S107 whether the estimated consumption amount (assumed consumption amount) of the thread calculated in step S 102 matches the actual consumption amount of the thread detected and calculated in steps S105 and S106 is compared, and a difference amount is detected.
  • step S108 the nipping pressure, which is a tension value, is adjusted in accordance with a difference (also referred to as deviation amount or difference amount) between the estimated consumption amount of the thread and the actual consumption amount of the thread to adjust the tension of the upper thread.
  • a difference also referred to as deviation amount or difference amount
  • the correlation table illustrated in FIG. 9 is referred to. As illustrated in FIG. 9 , when the consumption length of the thread until the actual color change is longer than estimated, the current embroidery is delayed with respect to the target thread consumption. Therefore, the correction value is set so as to weaken the tension of the thread with respect to the current value.
  • the correction value is set so as to increase the thread tension with respect to the current value.
  • the correction amount of the tension of the thread is set according to the type of the thread. For example, in the case of a thick thread (second thread type), the change in tension is increased, and in the case of a thin thread (first thread type), the change in tension is decreased.
  • a correlation table is illustrated as an example of the correlation stored in the correlation storage unit 607.
  • another correlation such as a correlation equation may be used.
  • the correlation table corresponding to the thread type as illustrated in FIG. 9 may be different depending on the temperature or humidity.
  • step S108 the tension value of the thread in step S108 is adjusted and the nipping pressure of the nipping rollers 18 is controlled by the roller pressing unit 183 with the adjusted tension value.
  • the tension of the upper thread is adjusted.
  • step S107 when the expected consumption amount of the thread is equal to the actual consumption amount of the thread in step S107, the embroidery operation is continued with the initial value of the tension, and the process proceeds to step S109.
  • step S109 it is determined whether the embroidery data includes a next color change scheduled in the upper thread. In the case of YES in step S109, the expected consumption amount (assumed consumption amount) of the thread until the next color change is calculated in step S110.
  • step S105 Thereafter, the embroidery operation is continued, and the process returns to step S105.
  • the detector 17 or 17A detects again that the color of the thread at the embroidery position has changed, the process of steps S105 to S110 are repeated until the next color change is not scheduled.
  • step S109 if the next color change is not scheduled in the needle thread (NO in step S109), the embroidery is continued until the end of the embroidery data.
  • FIG. 10 is a functional block diagram of a control section of an embroidery apparatus according to a second control example.
  • a computing mechanism 16A of the present control example includes a stitch-by-stitch thread-color prediction unit 601, an assumed-thread-consumption calculation unit 602, an embroidery-progress determination unit 603, an actual-thread-consumption calculation unit 604, a thread-consumption-progress calculation unit 605, a rotation-speed setting unit 608, and a correlation storage unit 609.
  • a stitch-by-stitch thread-color prediction unit 601 an assumed-thread-consumption calculation unit 602
  • an embroidery-progress determination unit 603 an actual-thread-consumption calculation unit 604
  • a thread-consumption-progress calculation unit 605 a rotation-speed setting unit 608, and a correlation storage unit 609.
  • the rotation speed of the drive roller 185 is adjusted as the adjustment of the nipping rollers 18A. Therefore, the rotation-speed setting unit 608 serving as a speed adjusting unit refers to the correlation data stored in the correlation storage unit 609 and sets the rotation speed so as to be corrected according to the difference (deviation amount) from the estimated value of the thread consumption amount.
  • a control signal is output to the rotary motor 187 to adjust the conveyance speed of a thread N.
  • FIG. 11 is a flowchart of the second control example.
  • FIG. 12 illustrates an example of a correlation table for correcting the consumption amount and the conveyance speed of the thread used in the third control example.
  • a correlation table illustrated in FIG. 12 is referred to.
  • the current embroidery is delayed with respect to the target thread consumption. Therefore, a correction value is set for correcting the speed of the thread to be faster than the current speed.
  • the consumption length of the thread until the actual color change is long, the color region of the thread is extended, or as illustrated in FIG. 4B , the tension of the upper thread in the stitch is strong due to the embroidery operation and the turnaround amount of the thread is small. Therefore, the conveyance speed is increased to weaken the tension of the thread, and as illustrated in FIG. 4C , the turnaround amount (feed amount) of the upper thread is increased and the consumption of the thread increases.
  • the current embroidery is advanced with respect to the target thread consumption. Therefore, as the correction of the conveyance speed of the thread, a correction value is set for correcting the speed of the thread to be slower than the current speed.
  • the color region of the thread is as illustrated in FIG. 4C , the tension of the upper thread in the stitch is weak due to the embroidery operation, and the turnaround amount of the thread is large. Therefore, the conveyance speed is reduced to increase the tension of the thread, and as illustrated in FIG. 4B , the turnaround amount (feed amount) of the upper thread is reduced and the consumption of the thread decreases.
  • a correlation table is illustrated as an example of the correlation stored in the correlation storage unit 607.
  • another correlation such as a correlation equation may be used.
  • correlation tables corresponding to the thread type may be prepared according to temperature and humidity.
  • FIG. 13 is a functional block diagram of a control section of an embroidery apparatus according to a third control example.
  • the pressing force (nipping pressure) of the nipping rollers 18 is controlled.
  • the thread conveyance speed is controlled by the rotation speed of the nipping rollers 18A.
  • both of the first control example and the second control example may be combined.
  • a computing mechanism 16B of the present control example includes a stitch-by-stitch thread-color prediction unit 601, an assumed-thread-consumption calculation unit 602, an embroidery-progress determination unit 603, an actual-thread-consumption calculation unit 604, a thread-consumption-progress calculation unit 605, a rotation-speed setting unit 608, a correlation storage unit 610, and a tension setting unit 606B.
  • the correlation storage unit 610 has a correlation table between the conveyance speed and the thread tension used for correction, in addition to the correlation table illustrated in FIG. 9 or 12 .
  • FIG. 14 is a flowchart of the second control example.
  • FIG. 15 illustrates an example of a correlation table between the thread conveyance speed and the thread tension for correction used in the third control example.
  • step S309 the tension value of the thread is adjusted, and the nipping pressure of the nipping rollers 18 is controlled by the roller pressing unit 183 with the adjusted tension value, thereby adjusting the tension of the upper thread.
  • step S310 the rotation speed of the drive roller 185 is controlled by the rotary motor 187 according to the difference (deviation amount) between the estimated consumption amount (assumed consumption amount) of the thread and the actual consumption amount of the thread.
  • the conveyance speed of the thread by the nipping rollers 18A is adjusted.
  • the rotation speed of the drive roller 185 is largely changed in order to largely change the tension, the following of the change of the tension may be delayed mechanically and electrically. Therefore, when the deviation amount of the thread consumption amount is large, it is preferable to directly adjust the tension.
  • the rotation speed of the drive roller 185 is changed to be small, fine adjustment is more effective for the tension of the upper thread than in the case where the tension is directly adjusted. Therefore, when the deviation amount of the thread consumption amount is small, it is preferable to adjust the rotation speed and finely adjust the conveyance speed of the upper thread.
  • the thread conveyance speed can be increased by reducing the pressing force (pressure of the nipping rollers 18) and setting the tension of the thread to be weak. That is, in the case where the consumption length of the thread until the actual color change is longer than estimated and the thread is stretched, or in the case where the pulling of the upper thread in the stitch is strong due to the embroidery operation and the turnaround amount is small, the conveyance speed of the thread is increased or the tension is reduced as the correction.
  • the thread conveyance speed can be reduced by increasing the pressing force and setting the thread tension to be strong. For example, in a case where the consumption length of the thread until the actual color change is shorter than estimated and the thread is shrunk, or in a case where the tension of the upper thread in the stitch is weak and the turnaround amount is large due to the embroidery operation, the conveyance speed of the thread is reduced or the tension is increased as the correction.
  • the correlation storage unit 610 stores two types of correlation tables including at least the correlation table between the thread conveyance speed and the thread tension as illustrated in FIG. 15 , such as the correlation table illustrated in FIG. 9 and the correlation table illustrated in FIG. 15 , or the correlation table illustrated in FIG. 12 and the correlation table illustrated in FIG. 15 .
  • adjustment can be performed by appropriately switching between adjustment of the thread conveyance speed and adjustment of the thread tension. For example, as illustrated in the flow of FIG. 14 , when the deviation amount of the thread consumption amount is small, the conveyance speed of the thread is adjusted. When the deviation amount is large, the tension of the thread is adjusted.
  • a correlation table is illustrated as an example of the correlation stored in the correlation storage unit 610.
  • another correlation such as a correlation equation may be used.
  • correlation tables corresponding to the thread type may be prepared according to temperature and humidity.
  • FIGS. 16 and 17 are diagrams illustrating examples of test patterns to be detected for creating a correlation table.
  • FIG. 16 is a diagram illustrating examples of a test pattern created by satin stitching for filling a surface.
  • the test pattern illustrated in FIG. 16 is formed by setting a diagonal line from the upper left to the lower right as the advancing direction of embroidery, designating the stitch direction as a downward right direction indicated by the arrow, passing the thread between adjacent sides and between diagonal vertices, and performing satin stitching while filling the quadrangle.
  • Pat (a) of FIG. 16 illustrates an example of a test pattern on the cloth in the case where the color change is as estimated.
  • Part (b) of FIG. 16 illustrates another example of the test pattern on the cloth in the case where the color change is later than estimated.
  • Part (c) of FIG. 16 illustrates still another example of the test pattern on the cloth in the case where the color change is earlier than estimated.
  • FIG. 17 is a diagram illustrating examples of test patterns created by straight stitching a rectangular wave.
  • the test patterns illustrated in FIG. 17 are described below in the case where the embroidery proceeds from left to right.
  • straight stitching is used in under-stitching and consumes the thread less and slower than satin stitching.
  • a marker is provided on the thread.
  • Part (a) of FIG. 17 illustrates an example of a test pattern on the cloth in the case where the position of the marker is as estimated.
  • Part (b) of FIG. 17 illustrates another example of the test pattern on the cloth in the case where the position of the marker is later than estimated.
  • Part (c) of FIG. 17 illustrates still another example of the test pattern on the cloth in the case where the position of the marker is earlier than estimated.
  • FIGS. 9 , 12 , and 15 illustrate examples in which the correction values are correlated so as to change linearly.
  • the amount of consumption per stitch changes according to the method in which the embroidery is sewn. Therefore, the correlation data of the tension adjustment with respect to the difference in the thread consumption amount and the correlation data of the conveyance speed adjustment with respect to the difference in the thread consumption amount may be set for each sewing method.
  • the same region might not be visually confirmed even if the same region in the same color is slightly shifted during embroidery.
  • the adjustment of the tension and the conveyance speed with respect to the nipping rollers is set such that the correction amount gradually changes so that the subsequent stitches after the correction gradually return to an appropriate position with respect to the previous stitch in which the deviation is detected.
  • the correction amount is set to a rapid change so that the stitch immediately returns to an appropriate position in the subsequent stitches after the correction with respect to the previous stitch in which the deviation is detected.
  • FIG. 18 is a schematic view of a dyeing embroidery apparatus according to a second embodiment of the present invention.
  • a dyeing unit 22 is provided in the preceding stage of an embroidery unit 21 having an embroidering function.
  • the dyeing unit 22 applies a color that changes in the conveyance direction to the upper thread unwound from the upper-thread spool.
  • the dyeing embroidery apparatus 2 includes the embroidery unit 21, the dyeing unit 22, and a controller 23, and is an in-line integrated-type apparatus.
  • the embroidery unit 21 performs embroidery on a cloth C using a needle 211.
  • the embroidery unit 21 includes the needle 211, a stage 213 serving as an embroidery feed unit, and a detector 217.
  • the needle 211 and the detector 217 are mounted on an embroidery head 201.
  • the embroidery unit 21 according to the present embodiment has a configuration and functions equivalent to those of the embroidery apparatus 1 according to the first embodiment except for the embroidery-data creating unit 15 and the computing mechanism 16.
  • an upper-thread spool 221 is provided not in the embroidery unit 21 but in the dyeing unit 22 on the upstream side in the conveyance direction.
  • the dyeing unit 22 includes the upper-thread spool 221, a dyeing device 222, and nipping rollers 228.
  • the upper-thread spool 221 is an upper thread supplier, around which the upper thread N is wound, to supply an upper thread N to the needle 211 via the dyeing device 222 and the nipping rollers 228.
  • the thread N unwound from the upper-thread spool 221 is white or monochromatic.
  • the dyeing device 222 dyes the thread N unwound from the upper-thread spool 221 with colors that change in the conveyance direction by a liquid discharge method.
  • the dyeing device 222 has a configuration capable of dying a thread using inks of four colors of black (K), cyan (C), magenta (M), and yellow (Y).
  • K black
  • C cyan
  • M magenta
  • Y yellow
  • a continuous upper thread may be dyed with a plurality of colors that change in the conveyance direction. Therefore, the number of colors that can be dyed by the dyeing device 222 may be any number as long as the colors correspond to at least two or more colors.
  • the nipping rollers 228 are conveyance rollers that convey the thread N dyed by the dyeing device 222 while pressing the thread N and feeds the thread N to the needle 211 of the embroidery unit 210.
  • the nipping rollers 228 have a configuration and function equivalent to those of the nipping rollers 18 (or 18A) illustrated in FIG. 6 .
  • the nipping rollers 228 can adjust the pressing force when the first control example and the third control example are performed, and can adjust the conveyance speed when the second control example and the third control example are performed.
  • the detector 217 in the embroidery unit 21 is provided in the vicinity of the needle 211, and detects the number of stitches (sewing operation information) indicating how many times the needle 211 has been sewn on the cloth, and the color of the thread N being embroidered.
  • the control unit 230 sends a control signal for instructing adjustment of the nipping pressure or speed of the nipping rollers 228 to the nipping rollers 228 according to the number of stitches and the detection timing of the color of the thread detected by the detector 217 of the embroidery unit 21.
  • the thread after the thread exits from the upper-thread spool 221, the thread is dyed by the dyeing device 222 and then fed to the embroidery unit 21. Accordingly, since the conveyance distance of the thread from the upper-thread spool 221 to the needle 211 is longer than that in the first embodiment, elongation or contraction of the thread is likely to occur during dyeing of the thread N while the thread N is fed from the dyeing device 222 to the embroidery head 201 or during conveyance after dyeing.
  • the nipping rollers 228 are adjusted in real time according to the detection result as described above.
  • Such a configuration can restrain the occurrence of the positional deviation of the color of the thread in the embroidery unit 210 due to the elongation and contraction of the thread that occurs before the thread N reaches the needle 211.
  • a fixing device 33 and a post-processing device 34 illustrated in FIG. 19 may be provided on the downstream side of the dyeing device 222 in the conveyance direction of the thread and on the upstream side of the nipping rollers 228 in the integrated-type dyeing embroidery apparatus according to the present embodiment.
  • FIG. 19 is a schematic side view of a dyeing embroidery system 100 according to a third embodiment of the present invention.
  • a dyeing apparatus 3 that applies colors, which change in the conveyance direction, to an upper thread wound from an upper-thread spool is provided in the preceding stage of an embroidery apparatus 1C.
  • the dyeing apparatus 3 and the embroidery apparatus 1C are not integrated.
  • the dyeing apparatus 3 includes, for example, an upper-thread spool 31 around which a upper thread N is wound, a dyeing device 32, a fixing device 33, and a post-processing device 34.
  • the upper thread N drawn from the upper-thread spool 31 is guided by a roller 351 and a roller 352, passes through the dyeing device 32 and nipping rollers 18C, and is continuously routed to a needle 11 of an embroidery head 10.
  • the dyeing device 32 includes a plurality of heads 321K, 321C, 321M, and 321Y and a plurality of individual maintenance units 322K, 322C, 322M, and 322Y
  • the plurality of heads 321K, 321C, 321M, and 321Y which may be collectively referred to as heads 321, discharge and apply liquids of colors to the upper thread N pulled out and fed from the upper-thread spool 31.
  • the plurality of individual maintenance units 322K, 322C, 322M, and 322Y which may be collectively referred to as maintenance units 322, perform maintenance of the heads 321K, 321C, 321M, and 321Y, respectively.
  • the plurality of heads 321K, 321C, 321M, and 321Y are discharge heads that discharge different colors.
  • the head 321K discharges droplets (ink) of black (K)
  • the head 321C discharges droplets of cyan (C)
  • the head 321M discharges droplets of magenta (M)
  • the head 321Y discharges droplets of yellow (Y).
  • the above-described order of colors is an example. In some embodiments, the colors may be arranged in an order different from the above-described order.
  • FIG. 13 an example in which the heads 321K, 321C, 321M, and 321Y of four colors are provided is illustrated. However, an embodiment of the present invention is not limited to the example. Since it is sufficient to dye a continuous upper thread with a plurality of colors that change in the conveyance direction, the number of heads may be any number as long as heads corresponding to a plurality of colors (in other words, at least two colors) are provided.
  • the maintenance units 322K, 322C, 322M, and 322Y are disposed below the heads 321K, 321C, 321M, and 321Y of the respective colors.
  • the maintenance units 322K, 322C, 322M, and 322Y for example, cap the heads 321K, 321C, 321M, and 321Y when the heads 321K, 321C, 321M, and 321Y are not in use, receive dummy discharge of liquid droplets from the heads 321K, 321C, 321M, and 321Y, perform suction circulating operation of the nozzles in a state in which a dummy discharge receptacle is close to the heads, and perform a wiping operation of the nozzles.
  • the dyeing device 32 in the dyeing apparatus 3 illustrated in FIG. 19 or the dyeing device 222 illustrated in FIG. 18 represents a configuration example of a liquid discharge type in which the upper thread N is dyed by discharging ink from the head 321.
  • the dyeing device 32 (or 222) may be a dyeing device of a coating type in which ink is applied by sandwiching an upper thread N with, for example, rollers.
  • the fixing device 33 performs a fixing process (drying process) of the ink discharged from the dyeing device 32 on the upper thread N.
  • the fixing device 33 includes heating means, such as an infrared irradiator or a warm-air blower, and heats and dries the upper thread N.
  • the post-processing device 34 includes, for example, a cleaner that cleans the upper thread N and lubricant applying means that applies a lubricant to a surface of the upper thread N.
  • the dyeing apparatus 3 includes at least the dyeing device 32 that applies a colored liquid to the upper thread N and may not include the fixing device 33 and the post-processing device 34.
  • the nipping rollers 18C are conveyance rollers (pressing conveyance rollers) that convey the thread N dyed by the dyeing apparatus 3 while applying pressure thereto and sends the thread N to the needle 11 of the embroidery head 10.
  • the nipping rollers 18C have a configuration and function equivalent to those of the nipping rollers 18 (or 18A) illustrated in FIG. 6 .
  • the nipping rollers 18C can adjust the pressing force when the first control example and the third control example are performed, and the nipping rollers 18C can adjust the conveyance speed when the second control example and the third control example are performed.
  • the detector 17 in the embroidery apparatus 1C is provided in the vicinity of the needle 11, and detects the number of stitches (sewing operation information) indicating how many times the needle 11 has been sewn on the cloth, and the color of the thread N being embroidered.
  • a computing mechanism 16 mounted in the embroidery head 10 adjusts the nipping pressure or speed at the nipping rollers (conveyance rollers) 18C according to the number of stitches and the detection timing of the color of the thread detected by the detector 17.
  • the thread is dyed in the dyeing device 32, is subjected to fixing and post-processing steps, and is then fed to the embroidery unit. Accordingly, since the conveyance distance of the thread from the upper-thread spool 31 to the needle 11 is longer than that in the first embodiment or the second embodiment, elongation or contraction of the thread is likely to occur during dyeing of the thread N while the thread N is fed from the dyeing device 32 to the embroidery head 10 or during conveyance after dyeing.
  • the pressure or conveyance speed of the nipping rollers 18C are adjusted in real time according to the detection result as described above.
  • Such a configuration can restrain the occurrence of the positional deviation of the color of the thread in the embroidery apparatus 1C due to the elongation and contraction of the thread that occurs before the thread N reaches the needle 11.
  • FIG. 20 is a schematic side view of a dyeing embroidery system according to a fourth embodiment of the present invention.
  • a host control apparatus 4 which is a higher-level apparatus, is connected to a dyeing embroidery system 100D.
  • the host control apparatus 4 is an information processing apparatus such as a computer.
  • the host control apparatus 4 is electrically connected to an embroidery apparatus 1D and a dyeing apparatus 3D via wired or wireless communication so as to exchange information between the embroidery apparatus 1D and the dyeing apparatus 3D.
  • nipping rollers 38 are disposed not in the embroidery apparatus 1D but in the dyeing apparatus 3D. As illustrated in FIGS. 19 and 20 , the nipping rollers 18C and the nipping rollers 38 may be disposed in either the dyeing apparatus or the embroidery apparatus.
  • FIG. 21 is a schematic block diagram of a dyeing embroidery system according to a fourth embodiment of the present invention.
  • a host control apparatus 4 includes an embroidery-data-and-dyeing-data creation unit 41 and a computing unit 42 in an executable manner.
  • the host control apparatus 4 includes the embroidery-data-and-dyeing-data creation unit 41 and the computing unit 42.
  • the embroidery-data-and-dyeing-data creation unit 41 acquires an embroidery image from which embroidery data is created, creates embroidery data based on the embroidery image and dyeing data corresponding to the embroidery image and the embroidery data, and outputs the embroidery data and the dyeing data to the computing unit 42.
  • the embroidery-data-and-dyeing-data creation unit 41 separates the embroidery image into colors (RGB values), determines the color of a thread to be used and the duration of each color on the thread so that sewing can be performed in a smooth order, based on the size of an embroidery pattern on a cloth, and creates embroidery data so that stitches are formed on the cloth using the thread of the determined color. Further, the embroidery-data-and-dyeing-data creation unit 41 creates dyeing data including information on the blending amount of each color of KCMY used for realizing the color of the thread included in the embroidery data and the continuous length of each color in the discharge head of KCMY colors.
  • the computing unit 42 of the host control apparatus 4 can communicate with a computing mechanism 36 in the dyeing apparatus 3D.
  • the computing unit 42 outputs dyeing data to the computing mechanism 36.
  • the computing mechanism 36 controls the dyeing device 32, the fixing device 33, and the post-processing device 34 based on the dyeing data.
  • the computing unit 42 can communicate with a computing mechanism 16D of the embroidery apparatus 1D and outputs the embroidery data to the computing mechanism 16D.
  • the computing mechanism 16D drives and controls a driver 191 based on the embroidery data.
  • the computing unit 42 also has the function of the roller controller 6 (or 6A or 6B) except for the embroidery-progress determination unit 603 in the computing mechanism 16 illustrated in FIGS. 7 , 10 , or 13 .
  • the computing unit 42 calculates the difference (deviation amount) in the consumption amount of the thread (or the consumption speed of the thread) based on the information of the current embroidery position obtained by the computing mechanism of the embroidery apparatus 1D based on the detection information by the detector 17, and sets the pressure to the nipping rollers 38 (or the pressure of the nipping rollers 38) or the conveyance speed based on the difference.
  • the computing unit 42 outputs a control signal indicating the set pressing force or rotation speed to the computing mechanism 36 of the dyeing apparatus 3D, and the computing mechanism 36 instructs a roller pressing unit 383 or a rotary motor 387 at the set pressing force or rotation speed.
  • Such control can restrain the occurrence of the positional deviation of the color of the thread in the embroidery apparatus 1D due to the elongation and contraction of the thread that occurs in the dyeing apparatus 3D before the thread N reaches the needle 11.

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  • Engineering & Computer Science (AREA)
  • Textile Engineering (AREA)
  • Chemical & Material Sciences (AREA)
  • Materials Engineering (AREA)
  • Sewing Machines And Sewing (AREA)
EP21199735.8A 2020-09-30 2021-09-29 Stickvorrichtung, färbende stickvorrichtung und färbendes sticksystem Withdrawn EP3978672A1 (de)

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JP2021131098A JP2022058181A (ja) 2020-09-30 2021-08-11 刺繍装置、染色・刺繍装置、及び染色・刺繍システム

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Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH06304359A (ja) * 1993-04-23 1994-11-01 Canon Inc 縫製機及びその刺繍製品
JP2008289522A (ja) 2007-05-22 2008-12-04 Seiko Epson Corp 刺繍装置、刺繍装置の制御方法およびプログラム
JP2009273675A (ja) * 2008-05-15 2009-11-26 Datsukusu:Kk 染色式刺繍機
WO2017013651A1 (en) * 2015-07-21 2017-01-26 Twine Solutions Ltd. An integrated system and method for treating a thread and using thereof

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH06304359A (ja) * 1993-04-23 1994-11-01 Canon Inc 縫製機及びその刺繍製品
JP2008289522A (ja) 2007-05-22 2008-12-04 Seiko Epson Corp 刺繍装置、刺繍装置の制御方法およびプログラム
JP2009273675A (ja) * 2008-05-15 2009-11-26 Datsukusu:Kk 染色式刺繍機
WO2017013651A1 (en) * 2015-07-21 2017-01-26 Twine Solutions Ltd. An integrated system and method for treating a thread and using thereof

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