JP6978209B2 - Sewing system - Google Patents

Description

The present invention relates to a sewing system.

In the garment manufacturing process, sewing machines as disclosed in Patent Document 1 and Patent Document 2 are used.

Japanese Unexamined Patent Publication No. 2016-131614 Japanese Unexamined Patent Publication No. 2016-131632

The garment is manufactured through a plurality of steps such as a step of stitching the fabric and the label and a step of stitching the fabric and the fabric. In order to suppress the decrease in the productivity of clothing, a technique capable of supplying the fabric to the sewing machine quickly and accurately is required.

It is an object of the present invention to provide a sewing system capable of suppressing a decrease in the productivity of clothing.

According to the aspect of the present invention, there is provided a sewing system including a sewing machine and a fabric transfer device that holds the fabric supplied from the fabric supply device and conveys the fabric to the sewing machine.

According to the aspect of the present invention, there is provided a sewing system capable of suppressing a decrease in the productivity of clothing.

FIG. 1 is a plan view schematically showing an example of a sewing system according to the present embodiment. FIG. 2 is a side sectional view schematically showing an example of the fabric position adjusting device according to the present embodiment. FIG. 3 is a perspective view in which a part of the fabric position adjusting device according to the present embodiment is broken. FIG. 4 is a side sectional view schematically showing an example of the first dough supply device according to the present embodiment. FIG. 5 is a perspective view showing an example of the suction member according to the present embodiment. FIG. 6 is a plan view showing an example of the suction member according to the present embodiment. FIG. 7 is a side view schematically showing an example of the operation of the movable member according to the present embodiment. FIG. 8 is a functional block diagram showing an example of the control device of the sewing system according to the present embodiment. FIG. 9 is a plan view schematically showing an example of the operation of the fabric transport device for transporting the front body according to the present embodiment. FIG. 10 is a plan view schematically showing an example of the operation of the fabric transport device for transporting the back body according to the present embodiment. FIG. 11 is a side view schematically showing an example of the operation of the dough transport device in the dough supply device according to the present embodiment. FIG. 12 is a perspective view schematically showing an example of the operation of the dough transport device in the first sewing machine according to the present embodiment. FIG. 13 is a diagram schematically showing each of the front body and the back body according to the present embodiment. FIG. 14 is a diagram schematically showing a state in which the front body and the back body according to the present embodiment are overlapped. FIG. 15 is a plan view schematically showing an example of the operation of the fabric position adjusting device in the second sewing machine according to the present embodiment. FIG. 16 is a plan view schematically showing an example of a front body and a back body in the second sewing machine according to the present embodiment. FIG. 17 is a plan view schematically showing an example of the operation of the second sewing machine according to the present embodiment. FIG. 18 is a plan view schematically showing an example of the operation of the dough transfer device in the second sewing machine according to the present embodiment. FIG. 19 is a plan view schematically showing an example of the operation of the dough transfer device in the second sewing machine according to the present embodiment. FIG. 20 is a plan view schematically showing an example of the operation of the second sewing machine according to the present embodiment. FIG. 21 is a flowchart showing an example of the operation of the sewing system according to the present embodiment.

Hereinafter, embodiments according to the present invention will be described with reference to the drawings, but the present invention is not limited thereto. The components of the embodiments described below can be combined as appropriate. In addition, some components may not be used.

In the following description, an XYZ Cartesian coordinate system will be set, and the positional relationship of each part will be described with reference to this XYZ Cartesian coordinate system. The direction parallel to the X-axis in the predetermined plane is the X-axis direction, the direction parallel to the Y-axis in the predetermined plane orthogonal to the X-axis is the Y-axis direction, and the direction parallel to the Z-axis orthogonal to the predetermined plane is Z. Axial direction. Further, the rotation direction or inclination direction centered on the X axis is set to the θX direction, the rotation direction or inclination direction centered on the Y axis is set to the θY direction, and the rotation direction or inclination direction centered on the Z axis is set to the θZ direction. .. Further, in the following description, the predetermined surface is appropriately referred to as an XY plane. In this embodiment, it is assumed that the XY plane and the horizontal plane are parallel.

[structure]
FIG. 1 is a plan view schematically showing an example of the sewing system 1 according to the present embodiment. As shown in FIG. 1, the sewing system 1 includes a sewing machine 2, a fabric supply device 3, and a fabric transfer device 4 that holds the fabric C supplied from the fabric supply device 3 and conveys the fabric C to the sewing machine 2.

The dough transfer device 4 has a robot 5 and a suction member 6 held by the robot 5. The robot 5 can move on the base member 7. In the XY plane, the base member 7 is arranged between the sewing machine 2 and the fabric supply device 3. The suction member 6 sucks and holds the dough C.

In the present embodiment, the sewing machine 2 includes a first sewing machine 21 and a second sewing machine 22. The dough supply device 3 includes a first dough supply device 31 and a second dough supply device 32. The dough C contains a first dough Ca and a second dough Cb. The first dough supply device 31 supplies the first dough Ca. The second dough supply device 32 supplies the second dough Cb.

In the present embodiment, the sewing system 1 manufactures a T-shirt as clothing. The first fabric Ca is the front body of the T-shirt. The second fabric Cb is the back body of the T-shirt. In the following description, the first dough Ca is appropriately referred to as a front body Ca, and the second dough Cb is appropriately referred to as a back body Cb.

<1st sewing machine>
The first sewing machine 21 is a label sewing machine that stitches the back body Cb and the label L together. Label L is a small piece of cloth. Label L contains information about clothing such as clothing size and fiber type, or handling precautions. The label L is supplied from the label supply device 8 to the first sewing machine 21 via the label transfer device 9.

The label supply device 8 supplies the label L. The label supply device 8 has a label accommodating member 84 in which a plurality of laminated labels L are accommodated, and a label transfer mechanism 85 for transferring the label L accommodated in the label accommodating member 84 to the label transfer device 9.

In the present embodiment, the label L includes a first label L1, a second label L2, and a third label L3. The label supply device 8 includes a first label supply device 81 that supplies the first label L1, a second label supply device 82 that supplies the second label L2, and a third label supply device 83 that supplies the third label L3. including. The first label supply device 81, the second label supply device 82, and the third label supply device 83 are arranged in the X-axis direction.

The label transport device 9 transports the label L supplied from the label supply device 8 to the first sewing machine 21. The label transfer device 9 has a clamp mechanism 91 for holding the label L, a guide mechanism 92 for guiding the clamp mechanism 91 in the X-axis direction, and an actuator 93 for generating power for moving the clamp mechanism 91 in the X-axis direction. .. The clamp mechanism 91 sequentially receives and holds the first label L1, the second label L2, and the third label L3 from the first label supply device 81, the second label supply device 82, and the third label supply device 83, respectively. do. The clamp mechanism 91 holds the first label L1, the second label L2, and the third label L3 in a laminated state. The actuator 93 generates power to move the clamp mechanism 91 holding the first label L1, the second label L2, and the third label L3 in the X-axis direction. The clamp mechanism 91 moves to the first sewing machine 21 while being guided by the guide mechanism 92 based on the power generated by the actuator 93. As a result, the first label L1, the second label L2, and the third label L3 are conveyed to the first sewing machine 21 in a laminated state.

The back body Cb is conveyed from the second dough supply device 32 to the first sewing machine 21 by the dough transfer device 4. The label L is conveyed from the label supply device 8 to the first sewing machine 21 by the label transfer device 9. The first sewing machine 21 sutures the back body Cb supplied from the second fabric supply device 32 and the label L supplied from the label supply device 8.

The first sewing machine 21 has a table 211 having an installation surface 211S on which the rear body Cb is installed, and a sewing machine head 212 for sewing the rear body Cb installed on the table 211 and the label L. The installation surface 211S includes the upper surface of the table 211. The installation surface 211S is substantially parallel to the XY plane. The dough transport device 4 transports the back body Cb to the table 211.

The sewing machine head 212 includes a drive mechanism 214 for moving the sewing machine needle 213 in the vertical direction, a first pressing member 215 for pressing the rear body Cb installed on the table 211 from above, and a second pressing member 216 for pressing the label L from above. And have. The rear body Cb is pressed by the first pressing member 215, and the label L installed on the rear body Cb is pressed by the second pressing member 216, and the sewing machine needle 213 moves in the vertical direction to move the rear body. Cb and label L are sutured. In the following description, the position where the suture is performed by the sewing machine needle 213 is appropriately referred to as the first suture position PM1. The first stitch position PM1 includes a needle drop position where the sewing machine needle 213 is lowered.

<Second sewing machine>
The second sewing machine 22 sutures the front body Ca and the back body Cb. In the present embodiment, the second sewing machine 22 is a shoulder-to-shoulder sewing machine that stitches the shoulder portion K of the front body Ca and the shoulder portion K of the back body Cb.

The front body Ca is conveyed from the first dough supply device 31 to the second sewing machine 22 by the dough transfer device 4. The back body Cb is transported from the first sewing machine 21 to the second sewing machine 22 by the fabric transport device 4. The back body Cb is conveyed from the first sewing machine 21 to the second sewing machine 22 with the label L sutured. The second sewing machine 22 stitches the front body Ca supplied from the first fabric supply device 31 and the back body Cb supplied from the second sewing machine 22.

The second sewing machine 22 has a table 221 having an installation surface 221S on which the front body Ca and the back body Cb are installed, and a sewing machine head 222 for suturing the front body Ca and the back body Cb installed on the table 221. The installation surface 221S includes the upper surface of the table 221. The installation surface 221S is substantially parallel to the XY plane. The dough transport device 4 transports each of the front body Ca and the back body Cb to the table 221.

The sewing machine head 222 has a drive mechanism 224 for moving the sewing machine needle 223 in the vertical direction, and a pressing member 225 for pressing the front body Ca and the rear body Cb installed on the table 221 from above. The front body Ca and the back body Cb are sutured by moving the sewing machine needle 223 in the vertical direction while the front body Ca and the back body Cb are pressed by the pressing member 225. In the following description, the position where the suture is performed by the sewing machine needle 223 is appropriately referred to as the second suture position PM2. The second stitch position PM2 includes the needle drop position where the sewing machine needle 223 is lowered.

Further, the second sewing machine 22 has a dough presser transport device 230 for transporting the front body Ca and the back body Cb on the table 221 and a dough presser for pressing and fixing the front body Ca and the back body Cb installed on the table 221 from above. A member 240 and a fabric position adjusting device 250 for adjusting the position of the front body Ca installed on the table 221 are provided.

The dough presser transfer device 230 includes a dough presser member 231 that presses the front body Ca and the back body Cb installed on the table 221 from above, a slider 233 that is connected to the dough presser member 231 via an arm member 232, and a slider 233. It has a guide member 234 that guides the slider 233 in the X-axis direction, and an actuator 235 that generates power to move the slider 233 in the X-axis direction.

The fabric pressing member 240 includes a first fabric pressing member 240L and a second fabric pressing member 240R. The first cloth holding member 240L and the second cloth holding member 240R are arranged in the X-axis direction. The first fabric pressing member 240L is arranged on the sewing machine head 222 side with respect to the second fabric pressing member 240R.

The fabric holding member 240 is supported by the table 221 via the support device 241. The support device 241 includes an actuator such as an air cylinder and supports the fabric holding member 240 so as to be movable at least in the Z-axis direction. The support device 241 may movably support the fabric pressing member 240 in at least one direction of the X-axis direction, the Y-axis direction, the θX direction, the θY direction, and the θZ direction. The support device 241 includes a first support device 241L that movably supports the first cloth holding member 240L, and a second support device 241R that movably supports the second cloth holding member 240R. The support device 241 including the first support device 241L and the second support device 241R can move the first cloth pressing member 240L and the second cloth pressing member 240R separately.

FIG. 2 is a side sectional view schematically showing an example of the fabric position adjusting device 250 according to the present embodiment. FIG. 3 is a perspective view in which a part of the fabric position adjusting device 250 according to the present embodiment is broken. The table 221 of the second sewing machine 22 has an installation surface 221S on which the fabric C is installed. The installation surface 221S includes the upper surface of the table 221. The installation surface 221S is substantially parallel to the XY plane.

The fabric position adjusting device 250 adjusts the position of at least a part of the front body Ca installed on the table 221. The fabric position adjusting device 250 adjusts the position of a part of the front body Ca in the XY plane.

The fabric position adjusting device 250 is provided on the installation surface 221S of the table 221 and has a plate member 251 having a holding surface 251S for holding the front body Ca, and is provided inside the table 221 and is a plate in a direction parallel to the installation surface 221S. It has an actuator 252 that moves the member 251 and adjusts the position of the front body Ca held by the plate member 251.

The holding surface 251S includes the upper surface of the plate member 251. The holding surface 251S is substantially parallel to the XY plane. The plate member 251 has a holding surface 251S, a lower surface 251T facing the opposite direction of the holding surface 251S, and a suction hole 253 penetrating the holding surface 251S and the lower surface 251T. A plurality of suction holes 253 are provided in the plate member 251 at intervals in a direction parallel to the holding surface 251S. The holding surface 251S and the installation surface 221S are substantially parallel to each other.

The installation surface 221S of the table 221 has an opening 221K. The plate member 251 is arranged so as to cover the opening 221K of the installation surface 221S. The installation surface 221S is arranged around the holding surface 251S. The outer edge region of the lower surface 251T of the plate member 251 and a part of the installation surface 221S around the opening 221K face each other.

The fabric position adjusting device 250 has a support member 254 that supports the plate member 251. At least a part of the support member 254 is fixed to the lower surface 251T of the plate member 251. The support member 254 is supported by the base member 255. The support member 254 and the base member 255 are installed in the internal space of the table 221.

The base member 255 is fixed to at least a part of the table 221 in the internal space of the table 221. The base member 255 movably supports the support member 254. The support member 254 is movably supported by the base member 255 in the XY plane. The support member 254 is supported by the base member 255 via, for example, a slide mechanism including a ball or roller. If the support member 254 is movable in the XY plane, the slide mechanism may not include a ball or a roller. The actuator 252 generates power to move the plate member 251. The actuator 252 is arranged, for example, between the support member 254 and the base member 255. If the support member 254 is movable with respect to the base member 255, the actuator 252 may not be arranged between the support member 254 and the base member 255. The actuator 252 moves the plate member 251 via the support member 254. The actuator 252 moves the plate member 251 fixed to the support member 254 in the XY plane by moving the support member 254. The base member 255 functions as a stator, and the support member 254 functions as a mover. By the operation of the actuator 252, the plate member 251 moves in the XY plane parallel to the installation surface 221S.

The support member 254 forms a space VS with the lower surface 251T of the plate member 251. The space VS between the plate member 251 and the support member 254 is connected to a vacuum system 70 including a vacuum pump and a control valve. The opening formed in a part of the support member 254 and the tube member 256 are connected to each other. The tube member 256 is flexible. The vacuum system 70 and the space VS are connected via a tube member 256.

When the space VS becomes a negative pressure due to the operation of the vacuum system 70, at least a part of the gas on the holding surface 251S side of the plate member 251 is sucked into the space VS through the suction hole 253. As shown in FIG. 2, by operating the vacuum system 70 with the front body Ca installed on the holding surface 251S, the front body Ca is adsorbed and held on the holding surface 251S.

The plate member 251 adsorbs and holds at least a part of the front body Ca on the holding surface 251S. The actuator 252 is operated while the front body Ca is attracted and held by the holding surface 251S, and the plate member 251 moves to adjust the position of the front body Ca held by the plate member 251. The fabric position adjusting device 250 adjusts the position of at least a part of the front body Ca installed on the table 221. The fabric position adjusting device 250 adjusts the position of a part of the front body Ca in the XY plane.

<Dough supply device>
The first dough supply device 31 supplies Ca to the front body. As shown in FIG. 1, the first fabric supply device 31 includes a storage device 311 for accommodating a plurality of front body Ca, an installation table 312 on which the front body Ca is installed, and a plurality of storage devices 311. It has a first pickup device that holds one front body Ca from the front body Ca and installs it on the installation table 312. A plurality of front body Cas are laminated in the accommodating device 311. The first pickup device holds one front body Ca arranged at the top of the plurality of stacked front body Ca and conveys it to the installation table 312. In the first pickup device, one front body Ca is installed on the installation table 312.

The second dough supply device 32 supplies the back body Cb. As shown in FIG. 1, the second dough supply device 32 includes an accommodating device 321 accommodating a plurality of rear body Cbs, an installation table 322 on which the rear body Cb is installed, and a plurality of accommodating devices 321. It has a second pickup device that holds one rear body Cb from the rear body Cb and installs it on the installation table 322. A plurality of back body Cbs are laminated in the accommodating device 321. The second pickup device holds one rear body Cb arranged at the top of the plurality of stacked rear body Cbs and conveys it to the installation table 322. In the second pickup device, one rear body Cb is installed on the installation table 322.

FIG. 4 is a side sectional view schematically showing an example of the first dough supply device 31 according to the present embodiment. The structure of the first dough supply device 31 and the structure of the second dough supply device 32 are substantially the same. Hereinafter, the first dough supply device 31 will be described, and the description of the second dough supply device 32 will be simplified or omitted.

As shown in FIG. 4, the first fabric supply device 31 has an installation table 312 on which the front body Ca is installed. One front body Ca is installed on the installation table 312. The installation table 312 has a plate member 33 and a support device 34 for supporting the plate member 33.

The plate member 33 has an upper surface 33S on which the front body Ca is installed, a lower surface 33T facing the opposite direction of the upper surface 33S, and a hole 37 penetrating the upper surface 33S and the lower surface 33T. The upper surface 33S and the lower surface 33T are parallel to each other. A plurality of holes 37 are provided in the plate member 33 at intervals in a direction parallel to the upper surface 33S.

The diameter φ of the holes 37 is smaller than the distance d between the adjacent holes 37. In the present embodiment, the diameter of the hole 37 is defined to be 2 [mm] or less.

The support device 34 supports the plate member 33 so that the upper surface 33S and the XY plane are parallel to each other. The support device 34 movably supports the plate member 33 in at least one direction in the θX direction, the θY direction, and the Z-axis direction.

The support device 34 has a base member 35 and a spring 36 arranged between the base member 35 and the plate member 33. The upper end of the spring 36 is connected to the plate member 33. The lower end of the spring 36 is connected to the base member 35. A plurality of springs 36 are arranged in the XY plane.

When no external force acts on the plate member 33, the upper surface 33S of the plate member 33 and the XY plane are substantially parallel. When an external force acts on the plate member 33, the upper surface 33S of the plate member 33 moves in at least one direction in the θX direction, the θY direction, and the Z-axis direction.

That is, in the present embodiment, the support device 34 including the spring 36 has a floating function of swingably supporting the plate member 33. When no external force acts on the plate member 33, the support device 34 supports the plate member 33 so that the upper surface 33S of the plate member 33 and the XY plane are substantially parallel to each other. When an external force acts on the plate member 33, the support device 34 supports the plate member 33 so that the upper surface 33S of the plate member 33 moves in at least one direction in the θX direction, the θY direction, and the Z-axis direction.

Further, the first fabric supply device 31 has a detection device 313 that detects the position of the front body Ca. The detection device 313 detects the position of the front body Ca in the XY plane. In the present embodiment, the detection device 313 includes an image pickup device that acquires an optical image of the front body Ca as image data. The detection device 313 is provided above the installation table 312. The detection device 313 detects the position of the front body Ca installed on the plate member 33 of the installation table 312. The detection device 313 acquires image data of the front body Ca installed on the plate member 33 of the installation table 312 from above the front body Ca.

Similarly, the second fabric supply device 32 has a detection device 323 that detects the position of the back body Cb. The detection device 323 detects the position of the back body Cb in the XY plane. In the present embodiment, the detection device 323 includes an image pickup device that acquires an optical image of the back body Cb as image data. The detection device 323 is provided above the installation table 322. The detection device 323 detects the position of the rear body Cb installed on the plate member 33 of the installation table 322. The detection device 323 acquires the image data of the rear body Cb installed on the plate member 33 of the installation table 322 from above the rear body Cb.

<Dough transfer device>
As shown in FIG. 1, the dough transfer device 4 has a robot 5 movably supported by the base member 7 and a suction member 6 held by the robot 5. In the present embodiment, the robot 5 is a horizontal articulated robot (SCARA: Selective Compliance Assembly Robot Arm). The robot 5 has an arm 51 for holding the suction member 6. The robot 5 can move in four directions of the X-axis direction, the Y-axis direction, the Z-axis direction, and the θZ-axis direction. The suction member 6 can move in four directions of the X-axis direction, the Y-axis direction, the Z-axis direction, and the θZ-axis direction while being held by the arm 51 of the robot 5.

The dough transfer device 4 uses the suction member 6 to suck and hold the dough C from above. The suction member 6 is connected to the vacuum system 70 and holds the dough C by suction from above.

The robot 5 can move on the base member 7. The robot 5 uses the suction member 6 at the first supply position PF1 facing the installation table 312 of the first fabric supply device 31, the second supply position PF2 facing the installation table 322 of the second fabric supply device 32, and the first sewing machine. It is movable to each of the first sewing machine position PH1 facing the table 211 of 21 and the second sewing machine position PH2 facing the table 221 of the second sewing machine 22. The first supply position PF1, the second supply position PF2, the first sewing machine position PH1, and the second sewing machine position PH2 are different positions in the XY plane. The suction member 6 can be moved above the installation table 312, above the installation table 322, above the table 211, and above the table 221 respectively.

FIG. 5 is a perspective view showing an example of the suction member 6 according to the present embodiment. FIG. 6 is a plan view showing an example of the suction member 6 according to the present embodiment.

As shown in FIGS. 5 and 6, the suction member 6 has a suction surface HS that sucks and holds the dough C from above. The suction surface HS includes the lower surface of the suction member 6. The suction surface HS is substantially parallel to the XY plane.

The suction member 6 has a main body member 60, a first suction member 61 that sucks and holds the dough C from above, and a second suction member 62 that sucks and holds the dough C from above. In the present embodiment, the suction surface HS includes a suction surface HS1 provided on the first suction member 61 and a suction surface HS2 provided on the second suction member 62.

The suction surface HS1 includes the lower surface of the first suction member 61. The suction surface HS1 is substantially parallel to the XY plane. In the XY plane, the outer shape of the suction surface HS1 is rectangular. The suction surface HS2 includes the lower surface of the second suction member 62. The suction surface HS2 is substantially parallel to the XY plane. In the XY plane, the outer shape of the suction surface HS2 is circular. The suction surface HS1 and the suction surface HS2 are arranged in the same plane. The suction surface HS1 of the first suction member 61 is larger than the suction surface HS2 of the second suction member 62.

The main body member 60 is a frame-shaped member. The main body member 60 includes a first member 60A, a second member 60B, a third member 60C, and a fourth member 60D. The first member 60A, the second member 60B, the third member 60C, and the fourth member 60D are rod-shaped members, respectively. The first member 60A and the second member 60B are arranged substantially in parallel. The third member 60C and the fourth member 60D are arranged substantially in parallel.

The first member 60A is longer than the second member 60B. The third member 60C is connected to one end of the first member 60A and one end of the second member 60B. The fourth member 60D is connected to the intermediate portion of the first member 60A and the other end of the second member 60B, respectively. The third member 60C is orthogonal to each of the first member 60A and the second member 60B. The fourth member 60D is orthogonal to each of the first member 60A and the second member 60B.

Further, the main body member 60 has a fifth member 60E and a sixth member 60F. The fifth member 60E and the sixth member 60F are rod-shaped members, respectively.

The fifth member 60E and the sixth member 60F are arranged between the third member 60C and the fourth member 60D. The third member 60C, the fourth member 60D, the fifth member 60E, and the sixth member 60F are arranged substantially in parallel. One end of the fifth member 60E is connected to the first member 60A. The other end of the fifth member 60E is connected to the second member 60B. One end of the sixth member 60F is connected to the first member 60A. The other end of the sixth member 60F is connected to the second member 60B. The fifth member 60E is arranged at a position closer to the third member 60C than the sixth member 60F.

The first suction member 61 is a box-shaped member having an internal space. The first suction member 61 has an upper plate 61A, a lower plate 61B, and a side plate 61C arranged between the upper plate 61A and the lower plate 61B.

The upper plate 61A is connected to a part of the first member 60A, a part of the second member 60B, the third member 60C, the fifth member 60E, and the sixth member 60F, respectively. The lower plate 61B has a suction surface HS1 that can face the fabric C. The suction surface HS1 is the lower surface of the lower plate 61B. The side plate 61C is a frame-shaped plate member, and is connected to each of the upper plate 61A and the lower plate 61B. The upper plate 61A, the lower plate 61B, and the side plate 61C define the internal space of the first suction member 61.

The lower plate 61B has a plurality of suction ports. The suction port includes a through hole penetrating the suction surface HS1 of the lower plate 61B and the upper surface. That is, the lower plate 61B is a perforated plate. The through hole connects the internal space and the external space of the first suction member 61. A plurality of suction ports are arranged on the lower surface of the lower plate 61B at regular intervals.

The suction member 6 has a connector 64 connected to the vacuum system 70. A plurality of connectors 64 are provided on the upper plate 61A. The connector 64 is connected to the internal space of the first suction member 61. When the vacuum system 70 operates, the gas in the internal space of the first suction member 61 is sucked into the vacuum system 70 via the connector 64. By operating the vacuum system 70 in a state where the suction surface HS1 of the lower plate 61B and the cloth C are in contact with each other, the first suction member 61 can suck and hold the cloth C from above on the suction surface HS1.

A plurality of second suction members 62 are provided. Each of the plurality of second suction members 62 has a suction surface HS2 that can face the fabric C.

The second suction member 62 has a suction port provided on the suction surface HS2. The suction port of the second suction member 62 is connected to the vacuum system 70. By operating the vacuum system 70 in a state where the suction surface HS2 of the second suction member 62 and the cloth C are in contact with each other, the second suction member 62 can suck and hold the cloth C from above on the suction surface HS2.

A part of the first member 60A protrudes from the fourth member 60D. Further, the suction member 6 has a first support member 65 and a second support member 66 that are movably supported by the fourth member 60D. Each of the first support member 65 and the second support member 66 is a rod-shaped member. The first member 60A, the first support member 65, and the second support member 66 are arranged substantially in parallel.

The first support member 65 is fixed to the fourth member 60D by the fixing mechanism 67. The fixing mechanism 67 fixes the first support member 65 so as to be releasable. The second support member 66 is fixed to the fourth member 60D by the fixing mechanism 68. The fixing mechanism 68 fixes the second support member 66 so as to be releasable.

The fourth member 60D has a guide mechanism 69 that guides the first support member 65 and the second support member 66 in the longitudinal direction of the fourth member 60D. Each of the first support member 65 and the second support member 66 can move in the longitudinal direction of the fourth member 60D while being guided by the guide mechanism 69 provided in the fourth member 60D.

When the fixing of the first support member 65 and the fourth member 60D by the fixing mechanism 67 is released, the first support member 65 is guided by the guide mechanism 69 and can move in the longitudinal direction of the fourth member 60D. When the first support member 65 and the fourth member 60D are fixed by the fixing mechanism 67, the position of the first support member 65 in the longitudinal direction of the fourth member 60D is fixed.

When the fixing of the second support member 66 and the fourth member 60D by the fixing mechanism 68 is released, the second support member 66 is guided by the guide mechanism 69 and can move in the longitudinal direction of the fourth member 60D. When the second support member 66 and the fourth member 60D are fixed by the fixing mechanism 68, the position of the second support member 66 in the longitudinal direction of the fourth member 60D is fixed.

The first member 60A protruding from the fourth member 60D supports a plurality of second suction members 62. The first support member 65 supports a plurality of second suction members 62. The second support member 66 supports a plurality of second suction members 62.

In the present embodiment, three second suction members 62 are provided at intervals in the longitudinal direction of the first member 60A. Three second suction members 62 are provided at intervals in the longitudinal direction of the first support member 65. Three second suction members 62 are provided at intervals in the longitudinal direction of the second support member 66. That is, in this embodiment, nine second suction members 62 are provided.

The position of the second suction member 62 is adjusted by moving the first support member 65 in the longitudinal direction of the fourth member 60D. The position of the second suction member 62 is adjusted by moving the second support member 66 in the longitudinal direction of the fourth member 60D. For example, by moving the first support member 65 and the second support member 66 according to the size of the fabric C, the suction position of the fabric C by the second suction member 62 is adjusted.

The suction member 6 has a connecting member 71 that is connected to the robot 5. The connecting member 71 is supported by a plate member 72 fixed to the fifth member 60E and the sixth member 60F. The connecting member 71 is a columnar member. In the longitudinal direction of the fifth member 60E and the sixth member 60F, the connecting member 71 is fixed to the central portion of the fifth member 60E and the central portion of the sixth member 60F.

The dough transfer device 4 has a movable member 63 that can be moved with respect to the suction member 6. The movable member 63 is movably supported by the suction member 6. In the present embodiment, the movable member 63 is movably supported by the third member 60C. In the longitudinal direction of the third member 60C, the dimension of the movable member 63 is smaller than the dimension of the third member 60C. As shown by the arrow Ra in FIG. 5, the movable member 63 can move in the vertical direction orthogonal to the suction surface HS. The movable member 63 is movable with respect to the suction surface HS of the suction member 6.

The suction member 6 has an actuator 73 that generates a power to move the movable member 63 in the vertical direction. The actuator 73 includes, for example, an air cylinder. The movable member 63 can be moved in the vertical direction by the operation of the actuator 73.

FIG. 7 is a side view schematically showing an example of the operation of the movable member 63 according to the present embodiment. As shown in FIG. 7A, when the movable member 63 is arranged at the upper end portion of the movable range in the vertical movable range of the movable member 63, the lower end portion of the movable member 63 sucks the suction member 6. It is arranged above the surface HS. In other words, when the movable member 63 is arranged at the upper end of the movable range, the lower end of the movable member 63 does not protrude below the suction surface HS of the suction member 6.

As shown in FIG. 7B, when the movable member 63 is arranged at the lower end of the movable range in the vertical movable range of the movable member 63, the lower end of the movable member 63 is attracted to the suction member 6. It is arranged below the surface HS. In other words, when the movable member 63 is arranged at the lower end of the movable range, the lower end of the movable member 63 protrudes below the suction surface HS of the suction member 6.

As shown in FIG. 7A, when the dough C is sucked and held by the suction surface HS, the lower end portion of the movable member 63 is arranged above the suction surface HS of the suction member 6. As shown in FIG. 7B, in a state where the dough C is not adsorbed and held on the adsorption surface HS, the lower end portion of the movable member 63 arranged below the adsorption surface HS of the adsorption member 6 is the dough C. Can be contacted with.

As shown in FIG. 6, the fabric C containing the front body Ca and the back body Cb has two shoulder portions K and two armpit portions W. The shoulder portion K includes the right shoulder portion KR and the left shoulder portion KL. The armpit portion W includes the right armpit portion WR and the left armpit portion WL.

The upper portion of the fabric C including the shoulder portion K is sucked and held by the first suction member 61. The suction surface HS1 of the first suction member 61 is sufficiently large, and the entire shoulder portion K can be sucked and held together. The suction member 6 can stably hold the upper portion of the fabric C while suppressing the misalignment of the shoulder portion K by using the first suction member 61.

The lower portion of the fabric C including the side portion W is sucked and held by the second suction member 62. The weight of the second suction member 62 is sufficiently smaller than the weight of the first suction member 61. Further, each of the first member 60A, the first support member 65, and the second support member 66 holding the second suction member 62 is a rod-shaped member and is lightweight. As a result, the weight of the suction member 6 can be reduced.

<Control device>
FIG. 8 is a functional block diagram showing an example of the control device 10 of the sewing system 1 according to the present embodiment. The sewing system 1 has a control device 10. The control device 10 includes a computer system and controls the sewing system 1. The control device 10 includes an arithmetic processing unit including a processor such as a CPU (Central Processing Unit), and a storage device including a memory and a storage such as a ROM (Read Only Memory) or a RAM (Random Access Memory). The arithmetic processing unit performs arithmetic processing according to a computer program stored in the storage apparatus.

As shown in FIG. 8, the control device 10 is a detection device arranged in the first sewing machine 21, the second sewing machine 22, the detection device 313 arranged in the first cloth supply device 31, and the detection device 32 arranged in the second cloth supply device 32. It is connected to each of 323 and the dough transfer device 4.

The control device 10 controls the front body position data acquisition unit 11 for acquiring the position data of the front body Ca, the rear body position data acquisition unit 12 for acquiring the position data of the rear body Cb, and the control signal for controlling the first sewing machine 21. The first sewing machine control unit 13 for outputting the data, the second sewing machine control unit 14 for outputting the control signal for controlling the second sewing machine 22, the transport control unit 15 for outputting the control signal for controlling the dough transport device 4, and the storage. It has a unit 16 and an input / output unit 17.

The front body position data acquisition unit 11 acquires the position data of the front body Ca based on the detection data of the detection device 313 arranged in the first fabric supply device 31. The front body position data acquisition unit 11 acquires the position data of the front body Ca in the XY plane. In the present embodiment, the detection device 313 acquires image data of the front body Ca installed on the installation table 312 as detection data. The detection device 313 acquires image data of the peripheral portion of the front body Ca including at least the shoulder portion K and the side portion W. The detection device 313 acquires the image data of the front body Ca together with the image data of the reference mark provided on the installation table 312. The reference mark may be provided on the optical system of the detection device 313. The front body position data acquisition unit 11 acquires the image data of the front body Ca and the image data of the reference mark from the detection device 313. The front body position data acquisition unit 11 performs image processing on the image data of the front body Ca and the image data of the reference mark. The front body position data acquisition unit 11 performs image processing on the image data of the front body Ca and the image data of the reference mark, and calculates the relative position between the reference mark and the peripheral portion of the front body Ca. The position data of the reference mark in the XY plane is known data and is stored in the storage unit 16. The front body position data acquisition unit 11 has the position data of the reference mark stored in the storage unit 16 and the relative position between the reference mark calculated based on the detection data of the detection device 313 and the peripheral portion of the front body Ca. Based on, the position data of the peripheral portion of the front body Ca in the XY plane is calculated.

The rear body position data acquisition unit 12 acquires the position data of the rear body Cb based on the detection data of the detection device 323 arranged in the second fabric supply device 32. The rear body position data acquisition unit 12 acquires the position data of the rear body Cb in the XY plane. Similar to the detection device 313, the detection device 323 acquires image data of the peripheral portion of the rear body Cb including at least the shoulder portion K and the side portion W together with the image data of the reference mark provided on the installation table 322. The reference mark may be provided on the optical system of the detection device 323. The rear body position data acquisition unit 12 has the position data of the reference mark stored in the storage unit 16 and the relative position between the reference mark calculated based on the detection data of the detection device 323 and the peripheral portion of the rear body Cb. Based on, the position data of the peripheral portion of the back body Cb in the XY plane is calculated.

The first sewing machine control unit 13 controls each of the label supply device 8, the label transfer device 9, and the sewing machine head 212.

The second sewing machine control unit 14 controls each of the support device 241, the fabric position adjusting device 250, and the sewing machine head 222.

The transport control unit 15 controls the fabric transport device 4 based on the position data of the front body Ca acquired by the front body position data acquisition unit 11. The transport control unit 15 moves the robot 5 in the XYZ Cartesian coordinate system defined in the sewing system 1. The movement amount of the robot 5 is detected by a movement amount sensor such as an encoder provided in the robot 5. The transport control unit 15 controls the movement amount of the robot 5 holding the front body Ca via the suction member 6 with reference to the position data of the front body Ca when it is installed on the installation table 312. , The front body Ca can be transported to the target position in the XY plane. Similarly, the transport control unit 15 controls the fabric transport device 4 based on the position data of the rear body Cb acquired by the rear body position data acquisition unit 12, so that the rear body Cb is placed at the target position in the XY plane. Can be transported.

[motion]
Next, an example of the operation of the sewing system 1 according to the present embodiment will be described.

<Transport route for front body>
FIG. 9 is a plan view schematically showing an example of the operation of the fabric transport device 4 for transporting the front body Ca according to the present embodiment. The dough transfer device 4 holds the front body Ca supplied from the first dough supply device 31 and conveys it to the second sewing machine 22. In the first fabric supply device 31, one front body Ca is installed on the installation table 312 by the first pickup device. The transfer control unit 15 controls the dough transfer device 4 to move the dough transfer device 4 to the first supply position PF1 facing the front body Ca installed on the installation table 312.

The dough transfer device 4 holds the front body Ca installed on the installation table 312 from above. The transport control unit 15 moves the fabric transport device 4 holding the front body Ca to the second sewing machine 22. The dough transfer device 4 holding the front body Ca in the first dough supply device 31 conveys the front body Ca to the second sewing machine 22. The dough transport device 4 transports the front body Ca one by one from the installation table 312.

The dough transfer device 4 adjusts the position of the front body Ca based on the detection result of the detection device 313. The transport control unit 15 controls the movement amount of the robot 5 based on the position data of the front body Ca acquired by the front body position data acquisition unit 11. As shown in FIG. 9, the transport control unit 15 controls the robot 5 to move the suction member 6 holding the front body Ca to the second sewing machine position PH2 facing the table 221 of the second sewing machine 22.

The dough transfer device 4 adjusts the position of the front body Ca in the second sewing machine 22 based on the detection result of the detection device 313. The transport control unit 15 adjusts the position of the fabric transport device 4 so that the front body Ca is arranged at the target position of the front body Ca defined in the second sewing machine 22. After the front body Ca is arranged at the target position of the front body Ca defined in the second sewing machine 22, the dough transfer device 4 releases the suction holding of the front body Ca by the suction surface HS. As a result, the front body Ca is passed to the second sewing machine 22 and installed on the table 221.

<Transport route for the back body>
FIG. 10 is a plan view schematically showing an example of the operation of the fabric transport device 4 for transporting the back body Cb according to the present embodiment. The dough transfer device 4 holds the rear body Cb supplied from the second dough supply device 32 and conveys it to the first sewing machine 21. In the second fabric supply device 32, one rear body Cb is installed on the installation table 322 by the second pickup device. The transfer control unit 15 controls the dough transfer device 4 to move the dough transfer device 4 to the second supply position PF2 facing the rear body Cb installed on the installation table 322.

The dough transfer device 4 holds the rear body Cb installed on the installation table 322 from above. The transport control unit 15 moves the fabric transport device 4 holding the back body Cb to the first sewing machine 21. The dough transfer device 4 holding the back body Cb in the second dough supply device 32 conveys the back body Cb to the first sewing machine 21. The dough transport device 4 transports the back body Cb one by one from the installation table 322.

The dough transfer device 4 adjusts the position of the back body Cb based on the detection result of the detection device 323. The transport control unit 15 controls the movement amount of the robot 5 based on the position data of the rear body Cb acquired by the rear body position data acquisition unit 12. As shown in FIG. 10, the transport control unit 15 controls the robot 5 to move the suction member 6 holding the rear body Cb to the first sewing machine position PH1 facing the table 211 of the first sewing machine 21.

The dough transfer device 4 adjusts the position of the rear body Cb in the first sewing machine 21 based on the detection result of the detection device 323. The transport control unit 15 adjusts the position of the fabric transport device 4 so that the rear body Cb is arranged at the target position of the rear body Cb defined in the first sewing machine 21.

In the present embodiment, the fabric transfer device 4 holds the back body Cb in the suture of the sewing machine head 212 of the first sewing machine 21. That is, in the stitching between the back body Cb and the label L in the first sewing machine 21, the fabric transfer device 4 continues to hold the back body Cb. The back body Cb is stitched to the label L in the first sewing machine 21 while being held by the fabric transport device 4.

The fabric transport device 4 transports the back body Cb from the first sewing machine 21 to the second sewing machine 22 after the stitching with the label L is completed. As shown in FIG. 10, the transport control unit 15 controls the robot 5 to move the suction member 6 holding the rear body Cb to the second sewing machine position PH2 facing the table 221 of the second sewing machine 22.

The dough transfer device 4 adjusts the position of the back body Cb in the second sewing machine 22 based on the detection result of the detection device 323. The transport control unit 15 controls the position of the fabric transport device 4 so that the rear body Cb is arranged at the target position of the rear body Cb defined in the second sewing machine 22. After the back body Cb is arranged at the target position of the back body Cb defined in the second sewing machine 22, the dough transfer device 4 releases the suction holding of the back body Cb by the suction surface HS. As a result, the back body Cb is passed to the second sewing machine 22 and installed on the table 221.

As described above, in the present embodiment, the fabric transfer device 4 transports the rear body Cb from the second fabric supply device 32 to the first sewing machine 21, sutures the first sewing machine 21, and the first sewing machine 21 to the second sewing machine 21. In transporting the back body Cb to the sewing machine 22, the back body Cb is continuously held.

In the present embodiment, when the front body Ca and the back body Cb supplied from the fabric supply device 3 are transported to the second sewing machine 22 by using a single robot 5 and the suction member 6, the transport route of the front body Ca is used. It is different from the transport route of the back body Cb. The front body Ca is directly conveyed from the first fabric supply device 31 to the table 221 of the second sewing machine 22. The back body Cb is conveyed from the second fabric supply device 32 to the table 221 of the second sewing machine 22 via the first sewing machine 21.

<Dough removal from the dough supply device>
FIG. 11 is a side view schematically showing an example of the operation of the dough transport device 4 in the dough supply device 3 according to the present embodiment. FIG. 11 is a diagram schematically showing an operation when the dough transport device 4 carries out the front body Ca from the installation table 312 of the first dough supply device 31.

The dough transport device 4 holds the front body Ca by vacuum suction from above and transports it. The support device 34 supports the plate member 33 at a position facing the suction surface HS of the suction member 6 of the dough transfer device 4.

With the front body Ca installed on the plate member 33 of the installation table 312, the detection device 313 acquires image data of the front body Ca. The image data of the front body Ca acquired by the detection device 313 is acquired by the front body position data acquisition unit 11. The front body position data acquisition unit 11 calculates the position of the front body Ca in the XY plane based on the image data of the front body Ca.

The hole 37 of the plate member 33 is minute. In the present embodiment, the diameter φ of the hole 37 of the plate member 33 is 2 [mm] or less. Therefore, even if the hole 37 is reflected in the image data of the front body Ca acquired by the detection device 313, it is suppressed from affecting the image processing in the front body position data acquisition unit 11.

The transfer control unit 15 moves the dough transfer device 4 to the first supply position PF1 facing the front body Ca installed on the plate member 33 of the installation table 312. After the dough transfer device 4 is moved to the first supply position PF1, the transfer control unit 15 lowers the dough transfer device 4 while performing the suction operation of the suction surface HS. As a result, the suction surface HS of the dough transfer device 4 and the front body Ca installed on the upper surface of the plate member 33 come into contact with each other, and the front body Ca is vacuum-sucked and held by the suction surface HS of the dough transfer device 4. The dough transfer device 4 vacuum sucks and holds the front body Ca installed on the upper surface 33S of the plate member 33 from above.

In the present embodiment, the plate member 33 is provided with a hole 37. As a result, when the gas is sucked from the suction hole of the suction surface HS of the dough transport device 4 in a state where the dough transport device 4 and the front body Ca installed on the plate member 33 are close to or in contact with each other, FIG. 11 shows. As shown by the arrow F, the gas in the space on the lower surface 33T side of the plate member 33 flows through the hole 37 into the space on the upper surface 33S side of the plate member 33. As a result, the vacuum suction holding of the front body Ca by the suction surface HS of the dough transport device 4 is stably carried out.

In the present embodiment, the robot 5 is a horizontal articulated robot and can move in four directions of the X-axis direction, the Y-axis direction, the Z-axis direction, and the θZ direction. The suction surface HS of the dough transfer device 4 can move in the X-axis direction, the Y-axis direction, the Z-axis direction, and the θZ direction. The support device 34 has a floating function of swingably supporting the plate member 33. The plate member 33 is movably supported by the support device 34 in at least one direction in the θX direction, the θY direction, and the Z-axis direction.

That is, in the present embodiment, the plate member 33 that supports the front body Ca is in the θX direction, the θY direction, and the θY direction with respect to the suction surface HS of the fabric transport device 4 that can move only in the XY plane and in the Z axis direction. It can move in the Z-axis direction. Therefore, even if the suction surface HS of the dough transfer device 4 and the upper surface 33S of the plate member 33 are not parallel, the dough transfer device 4 is lowered and installed on the suction surface HS of the dough transfer device 4 and the upper surface 33S of the plate member 33. When the front body Ca is brought into contact with the front body Ca, the plate member 33 swings so that the suction surface HS of the fabric transport device 4 and the upper surface 33S of the plate member 33 are parallel to each other. As a result, the suction surface HS of the dough transfer device 4 and the upper surface 33S of the plate member 33 can be sufficiently in contact with each other, and the front body Ca is stably vacuum-sucked and held by the suction surface HS of the dough transfer device 4. ..

In addition, referring to FIG. 11, the operation of the dough transport device 4 carrying out the front body Ca from the first dough supply device 31 has been described. The operation of the dough transfer device 4 to carry out the rear body Cb from the second dough supply device 32 is the same as the operation of carrying out the front body Ca from the first dough supply device 31, so the description thereof will be omitted.

<Operation of the dough transfer device in the first sewing machine>
FIG. 12 is a perspective view schematically showing an example of the operation of the fabric transfer device 4 in the first sewing machine 21 according to the present embodiment.

The first sewing machine 21 cooperates with the fabric transport device 4 to sew the back body Cb and the label L. As shown in FIG. 12, the first sewing machine 21 has a table 211 having an installation surface 211S on which the rear body Cb is installed, and a sewing machine head 212 for stitching the rear body Cb installed on the table 211 and the label L. Have.

The sewing machine head 212 includes a drive mechanism 214 for moving the sewing machine needle 213 in the vertical direction, a first pressing member 215 for pressing the rear body Cb installed on the table 211 from above, and a label L installed on the rear body Cb. It has a second pressing member 216 that presses from above.

The fabric transfer device 4 holds the back body Cb when the back body Cb and the label L are sewn together by the sewing machine head 212. The transport control unit 15 moves the fabric transport device 4 based on the detection result of the detection device 313 so that the label L is sewn to the target portion of the back body Cb. In the present embodiment, the transport control unit 15 is held by the fabric transport device 4 based on the detection result of the detection device 313 so that the target portion of the side portion W of the back body Cb is arranged at the first suture position PM1. Adjust the position of the back body Cb.

In the present embodiment, the first sewing machine 21 is provided with a position sensor 217 that detects the position of the side portion W of the rear body Cb. The position sensor 217 irradiates the peripheral portion of the rear body Cb with the detection light, and optically detects the position of the side portion W. The transport control unit 15 is a fabric transport device 4 that holds the back body Cb based on the detection result of the position sensor 217 so that the target portion of the side portion W of the rear body Cb is arranged at the first suture position PM1. Adjust the position. That is, in the present embodiment, the transport control unit 15 adjusts the relative position between the target portion of the side portion W of the back body Cb and the first suture position PM1 based on the detection result of the position sensor 217.

The sewing machine head 212 sutures the back body Cb and the label L while feeding the back body Cb and the label L in the sewing direction. The fabric transfer device 4 holds the back body Cb and moves in the sewing direction in synchronization with the stitching of the sewing machine head 212. In the example shown in FIG. 12, the sewing direction is the X-axis direction.

The first sewing machine control unit 13 controls the first sewing machine 21 so that the back body Cb and the label L are sewn while being fed in the specified sewing direction. The first sewing machine 21 moves the sewing machine needle 213 in the vertical direction while feeding the back body Cb and the label L in the specified sewing direction, and sews the back body Cb and the label L. The transport control unit 15 moves the fabric transport device 4 holding the rear body Cb in the specified sewing direction in synchronization with the feed operation of the rear body Cb and the label L in the sewing direction by the first sewing machine 21. The fabric transfer device 4 moves in the specified sewing direction while holding the back body Cb in synchronization with the feeding operation of the back body Cb and the label L by the first sewing machine 21 in the sewing direction. As a result, the back body Cb and the label L are smoothly sutured by the first sewing machine 21.

In the present embodiment, the dough transfer device 4 presses the back body Cb against the table 211. The transfer control unit 15 moves the fabric transfer device 4 in a predetermined sewing direction while pressing the fabric transfer device 4 against the table 211 so that a load larger than the weight of the fabric transfer device 4 acts on the table 211.

In the present embodiment, the target portion of the side portion W of the back body Cb to be sewn with the label L is arranged between the pair of second suction members 62 provided on the first member 60A. The target portion of the armpit portion W to be sewn with the label L is not covered with the suction member 6. As a result, the first pressing member 215 and the second pressing member 216 can smoothly press the side portion W of the rear body Cb from above. Further, since the target portion of the side portion W to be sutured with the label L is not covered with the suction member 6, the suture by the sewing machine needle 213 is smoothly performed.

<Operation of the dough transfer device and the dough position adjustment device in the second sewing machine>
Next, an example of the operation of the dough transfer device 4 and the dough position adjusting device 250 in the second sewing machine 22 will be described. As described above, in the present embodiment, the second sewing machine 22 is a shoulder-to-shoulder sewing machine that stitches the shoulder portion K of the front body Ca and the shoulder portion K of the rear body Cb.

FIG. 13 is a diagram schematically showing each of the front body Ca and the back body Cb according to the present embodiment. As shown in FIG. 13, the front body Ca has two shoulder portions K and two armpit portions W. The back body Cb has two shoulder portions K and two armpit portions W. The two shoulder portions K include a left shoulder portion KL, which is one shoulder portion K, and a right shoulder portion KR, which is the other shoulder portion K. The two armpits W include a left armpit WL, which is one armpit W, and a right armpit WR, which is the other armpit W. In the second sewing machine 22, the left shoulder portion KL of the front body Ca and the left shoulder portion KL of the back body Cb are sutured, and the right shoulder portion KR of the front body Ca and the right shoulder portion KR of the back body Cb are sutured. To.

FIG. 14 is a diagram schematically showing a state in which the front body Ca and the back body Cb according to the present embodiment are overlapped. As shown in FIG. 14, when the shoulder portion K of the front body Ca and the shoulder portion K of the back body Cb are sewn together, the front body Ca and the back body Cb are overlapped with each other in the second sewing machine 22. When the front body Ca and the back body Cb are overlapped, the position of the shoulder portion K of the front body Ca and the position of the shoulder portion K of the back body Cb may not match. For example, as shown in FIG. 14, when the front body Ca and the back body Cb are overlapped so that the position of the left shoulder portion KL of the front body Ca and the position of the left shoulder portion KL of the back body Cb coincide with each other, the front body There is a possibility that the position of the right shoulder portion KR of Ca and the position of the right shoulder portion KR of the back body Cb are misaligned. The reason why the position of the shoulder portion K of the front body Ca and the position of the shoulder portion K of the rear body Cb do not match is, for example, stretching or cutting misalignment of the fabric C.

If the position of the shoulder part K of the front body Ca and the position of the shoulder part K of the back body Cb do not match, and the shoulder part K of the front body Ca and the shoulder part K of the back body Cb are sutured, it is defective. Calcium is manufactured.

The fabric position adjusting device 250 corrects the deviation between the position of the shoulder portion K of the front body Ca and the position of the shoulder portion K of the rear body Cb. When the fabric position adjusting device 250 superimposes the front body Ca and the back body Cb so that the position of the left shoulder portion KL of the front body Ca and the position of the left shoulder portion KL of the back body Cb match, the front body Ca The position of the right shoulder portion KR of the front body Ca is adjusted so that the amount of deviation G between the position of the right shoulder portion KR and the position of the right shoulder portion KR of the rear body Cb becomes small.

Before the front body Ca is transported to the second sewing machine 22, the position of the left shoulder portion KL of the front body Ca and the position of the right shoulder portion KR of the front body Ca in the XY plane are arranged in the first fabric supply device 31. It is detected by the detection device 313. Before the rear body Cb is conveyed to the second sewing machine 22, the position of the left shoulder portion KL of the rear body Cb and the position of the right shoulder portion KR of the rear body Cb in the XY plane are arranged in the second fabric supply device 32. It is detected by the detection device 323.

The front body position data acquisition unit 11 calculates the position data of the left shoulder portion KL of the front body Ca and the position data of the right shoulder portion KR of the front body Ca in the XY plane based on the image data acquired by the detection device 313. do. The rear body position data acquisition unit 12 calculates the position data of the left shoulder portion KL of the rear body Cb and the position data of the right shoulder portion KR of the rear body Cb in the XY plane based on the image data acquired by the detection device 323. do.

The second sewing machine control unit 14 has the position data of the left shoulder portion KL of the front body Ca calculated by the front body position data acquisition unit 11, the position data of the right shoulder portion KR of the front body Ca, and the rear body position data acquisition unit 12. Based on the position data of the left shoulder part KL of the back body Cb and the position data of the right shoulder part KR of the back body Cb calculated in, the position of the left shoulder part KL of the front body Ca and the position of the left shoulder part KL of the back body Cb. Calculate the amount of deviation G between the position of the right shoulder part KR of the front body Ca and the position of the right shoulder part KR of the back body Cb when the front body Ca and the back body Cb are superposed so as to match. .. The deviation amount G calculated by the second sewing machine control unit 14 is stored in the storage unit 16.

FIG. 15 is a plan view schematically showing an example of the operation of the fabric position adjusting device 250 in the second sewing machine 22 according to the present embodiment. FIG. 15 schematically shows the front body Ca transported from the first dough supply device 31 to the table 221 of the second sewing machine 22 by the dough transfer device 4.

Based on the detection result of the detection device 313, the dough transport device 4 transports the front body Ca to the table 221 so that the front body Ca is installed at the target position defined in the second sewing machine 22. In the dough transfer device 4, the left shoulder portion KL of the front body Ca is installed on the installation surface 221S of the table 221 and the right shoulder portion KR of the front body Ca is installed on the holding surface 251S of the plate member 251 of the fabric position adjusting device 250. As described above, the front body Ca is transported to the table 221.

After the front body Ca is installed on the table 221 the fabric position adjusting device 250 performs a suction operation by the suction hole 253 to suck and hold the right shoulder portion KR of the front body Ca on the holding surface 251S of the plate member 251. .. As a result, the right shoulder portion KR of the front body Ca is held on the holding surface 251S of the plate member 251 in a state where the left shoulder portion KL of the front body Ca is installed on the installation surface 221S of the table 221.

The second sewing machine control unit 14 controls the actuator 252 of the fabric position adjusting device 250 to move the plate member 251 in the direction parallel to the installation surface 221S, and adjusts the position of the right shoulder portion KR of the front body Ca. .. The second sewing machine control unit 14 sucks and holds the right shoulder portion KR so that the deviation amount G calculated based on the detection result of the detection device 313 and the detection result of the detection device 323 and stored in the storage unit 16 becomes small. The plate member 251 is moved in a direction parallel to the installation surface 221S.

That is, in the second sewing machine control unit 14, the amount of deviation G between the right shoulder portion KR of the front body Ca installed on the table 221 and the right shoulder portion KR of the rear body Cb later transported to the table 221 becomes small. As described above, the actuator 252 is controlled to adjust the amount of movement of the plate member 251 holding the right shoulder portion KR of the front body Ca.

As a result, as shown in FIG. 15, the position of the right shoulder portion KR of the front body Ca is adjusted from the position shown by the dotted line to the position shown by the solid line. Even if the right shoulder portion KR of the front body Ca moves due to the movement of the plate member 251, the left shoulder portion KL of the front body Ca is substantially stationary due to the frictional force with the installation surface 221S of the table 221. A suction port connected to the vacuum system 70 may be provided on the installation surface 221S of the table 221, and the left shoulder portion KL of the front body Ca may be suction-held on the installation surface 221S of the table 221. The left shoulder portion KL of the front body Ca is adsorbed and held on the installation surface 221S of the table 221, so that even if the right shoulder portion KR of the front body Ca moves due to the movement of the plate member 251, it is adsorbed on the installation surface 221S of the table 221. The left shoulder portion KL of the held front body Ca is substantially stationary.

The fabric position adjusting device 250 moves the plate member 251 that adsorbs and holds the right shoulder portion KR of the front body Ca in the XY plane in a state where the left shoulder portion KL of the front body Ca is installed on the installation surface 221S of the table 221. Thereby, it is possible to adjust the relative position between the right shoulder portion KR of the front body Ca held on the holding surface 251S and the left shoulder portion KL of the front body Ca installed on the installation surface 221S in the XY plane. can.

After the position of the right shoulder portion KR of the front body Ca installed on the table 221 is adjusted by the dough position adjusting device 250, the back body Cb is transferred to the table 221 of the second sewing machine 22 by the dough transfer device 4. .. Based on the detection result of the detection device 323, the transport control unit 15 controls the fabric transport device 4 so that the rear body Cb is arranged at the target position specified in the table 221 to determine the position of the rear body Cb. adjust. The dough transfer device 4 adjusts the position of the back body Cb with respect to the front body Ca installed on the table 221 so that the front body Ca installed on the table 221 of the second sewing machine 22 and the back body Cb overlap each other. ..

Based on the detection results of the detection device 313 and the detection device 323, the transfer control unit 15 is transported to the table 221 by the left shoulder portion KL of the front body Ca installed on the installation surface 221S of the table 221 and the fabric transfer device 4. The dough transfer device 4 is controlled so as to coincide with the left shoulder portion KL of the back body Cb. As a result, the position of the left shoulder portion KL of the front body Ca and the position of the left shoulder portion KL of the rear body Cb on the installation surface 221S of the table 221 coincide with each other on the front body Ca installed on the table 221. The body Cb is transported. After the back body Cb is transferred to the table 221 by the dough transfer device 4, the transfer control unit 15 releases the suction holding of the back body Cb by the suction surface HS of the suction member 6.

FIG. 16 is a plan view schematically showing an example of the front body Ca and the back body Cb in the second sewing machine 22 according to the present embodiment. Before the back body Cb is conveyed to the table 221 the second sewing machine control unit 14 controls the actuator 252 of the fabric position adjusting device 250 so that the deviation amount G becomes small, and the holding surface 251S of the plate member 251S. The relative position between the right shoulder portion KR of the front body Ca held by the fabric transfer device 4 and the right shoulder portion KR of the rear body Cb conveyed by the dough transfer device 4 is adjusted. The second sewing machine control unit 14 controls the actuator 252 of the fabric position adjusting device 250 to position the right shoulder portion KR of the front body Ca and the position of the right shoulder portion KR of the rear body Cb on the holding surface 251S of the plate member 251. The plate member 251 is moved so as to match with. That is, the relative position between the right shoulder portion KR and the left shoulder portion KL of the front body Ca installed on the table 221 by the fabric position adjusting device 250 is the right shoulder portion KR of the back body portion Cb conveyed by the fabric transport device 4. And the left shoulder part KL are adjusted to match the relative position. Therefore, as shown in FIG. 16, the back body Cb is transported onto the front body Ca installed on the table 221 by the dough transport device 4, so that the right shoulder portion KR of the front body Ca is transported on the table 221. The position of the front body Ca and the position of the left shoulder part KL of the back body Cb match, and the position of the left shoulder part KL of the front body Ca and the position of the left shoulder part KL of the back body Cb match. It overlaps with Cb.

FIG. 17 is a plan view schematically showing an example of the operation of the second sewing machine 22 according to the present embodiment. The position of the right shoulder part KR of the front body Ca and the position of the right shoulder part KR of the back body Cb match, and the position of the left shoulder part KL of the front body Ca and the position of the left shoulder part KL of the back body Cb match. After the front body Ca and the back body Cb are overlapped with each other, as shown in FIG. 17, the second sewing machine control unit 14 is the first cloth pressing member 240L, and the left shoulder portion KL and the back body Cb of the front body Ca are used. Fix the left shoulder part KL of. The left shoulder portion KL of the front body Ca and the left shoulder portion KL of the rear body Cb are fixed between the first fabric pressing member 240L and the table 221 by being pressed from above by the first fabric pressing member 240L.

18 and 19 are plan views schematically showing an example of the operation of the dough transfer device 4 in the second sewing machine 22 according to the present embodiment. After the left shoulder portion KL of the front body Ca and the left shoulder portion KL of the rear body Cb are fixed by the first fabric pressing member 240L, as described with reference to FIG. 7B, the transport control unit 15 is a movable member. The movable member 63 of the suction member 6 is lowered so that the lower end portion of the 63 is arranged below the suction surface HS.

The transport control unit 15 adjusts the position of the fabric transport device 4 to bring the lower end portion of the movable member 63 into contact with the rear body Cb. The transport control unit 15 controls the robot 5 in a state where at least a part of the rear body Cb and the movable member 63 are in contact with each other, and moves the movable member 63 in contact with at least a part of the rear body Cb in the XY plane. Then, the position of the rear body Cb and the position of the front body Ca in the XY plane are adjusted.

As shown in FIG. 18, in the present embodiment, the transfer control unit 15 moves the fabric transfer device 4 in the XY plane in a state where the vicinity of the right shoulder portion KR of the fabric C and the movable member 63 are in contact with each other. Then, the position of the right shoulder portion KR with respect to the left shoulder portion KL fixed to the first fabric pressing member 240L is adjusted. As shown in FIG. 19, the transport control unit 15 adjusts the position of the right shoulder portion KR with respect to the left shoulder portion KL so that the right shoulder portion KR and the left shoulder portion KL are arranged linearly.

FIG. 20 is a plan view schematically showing an example of the operation of the second sewing machine 22 according to the present embodiment. After the position of the right shoulder portion KR with respect to the left shoulder portion KL is adjusted, as shown in FIG. 20, the second sewing machine control unit 14 fixes the right shoulder portion KR with the second fabric pressing member 240R. As a result, the seam line SL of the left shoulder portion KL and the seam line SR of the right shoulder portion KR are arranged on the same straight line.

[procedure]
FIG. 21 is a flowchart showing an example of the operation of the sewing system 1 according to the present embodiment. Of the plurality of front body Ca stacked on the accommodating device 311 of the first fabric supply device 31, one front body Ca arranged at the top is conveyed to the installation table 312 by the first pickup device. The front body Ca installed on the installation table 312 is detected by the detection device 313. Of the plurality of rear body Cbs stacked on the accommodating device 321 of the second fabric supply device 32, one rear body Cb arranged at the top is conveyed to the installation table 322 by the second pickup device. The rear body Cb installed on the installation table 322 is detected by the detection device 323. The front body position data acquisition unit 11 calculates the position data of the front body Ca in the XY plane based on the detection data of the detection device 313. The rear body position data acquisition unit 12 calculates the position data of the rear body Cb in the XY plane based on the detection data of the detection device 323 (step S10).

The position data of the front body Ca includes the position data of the peripheral portion of the front body Ca including the left shoulder portion KL, the right shoulder portion KR, the left armpit portion WL, and the right armpit portion WR in the XY plane. The position data of the back body Cb includes the position data of the peripheral portion of the back body Cb including the left shoulder portion KL, the right shoulder portion KR, the left armpit portion WL, and the right armpit portion WR in the XY plane.

The second sewing machine control unit 14 has the position data of the left shoulder portion KL of the front body Ca calculated in step S10, the position data of the right shoulder portion KR of the front body Ca, the position data of the left shoulder portion KL of the rear body Cb, and the rear. Based on the position data of the right shoulder part KR of the body Cb, the front body Ca and the back body Cb are superposed so that the position of the left shoulder part KL of the front body Ca and the position of the left shoulder part KL of the back body Cb match. The amount of deviation G between the position of the right shoulder portion KR of the front body Ca and the position of the right shoulder portion KR of the rear body Cb at the time is calculated. The storage unit 16 stores data indicating the calculated deviation amount G.

The transfer control unit 15 controls the dough transfer device 4 to transfer the front body Ca from the first dough supply device 31 to the second sewing machine 22 (step S20).

The transfer control unit 15 moves the dough transfer device 4 to the first supply position PF1. The transport control unit 15 sucks and holds one front body Ca installed on the installation table 312 of the first dough supply device 31 on the suction surface HS of the dough transport device 4. The transport control unit 15 moves the fabric transport device 4 holding the front body Ca to the second sewing machine position PH2. The transfer control unit 15 transfers the front body Ca to the target position specified in the table 221 of the second sewing machine 22 so that the front body Ca is held by the fabric transfer device 4 at the second sewing machine position PH2. Adjust the position of.

In the present embodiment, in the transport control unit 15, the left shoulder portion KL of the front body Ca is installed on the installation surface 221S of the table 221 and the right shoulder portion KR of the front body Ca is provided on the table 221 to hold the plate member 251. The front body Ca is transported to the table 221 by the dough transport device 4 so as to be installed on the surface 251S.

The transport control unit 15 transports the front body Ca to the table 221 of the second sewing machine 22 by the dough transport device 4, adjusts the position of the front body Ca, and then adsorbs the front body Ca by the suction surface HS of the dough transport device 4. Release the hold. As a result, the front body Ca is passed to the table 221 of the second sewing machine 22. After the front body Ca is passed from the dough transfer device 4 to the table 221 of the second sewing machine 22, the transfer control unit 15 moves the dough transfer device 4 to the second supply position PF2.

The second sewing machine control unit 14 controls the fabric position adjusting device 250 to adjust the position of the right shoulder portion KR of the front body Ca installed on the table 221 (step S30A).

As described with reference to FIG. 15, the right shoulder portion KR of the front body Ca is adsorbed and held by the plate member 251. The left shoulder portion KL of the front body Ca is installed on the installation surface 221S of the table 221. The second sewing machine control unit 16 controls the actuator 252 of the fabric position adjusting device 250 to move the plate member 251 in the direction parallel to the installation surface 221S, so that the deviation amount G stored in the storage unit 16 is small. The plate member 251 that attracts and holds the right shoulder portion KR is moved in a direction parallel to the installation surface 221S.

In parallel with at least a part of the process of adjusting the position of the right shoulder portion KR of the front body Ca by the dough position adjusting device 250, the transfer control unit 15 controls the dough transfer device 4 from the second dough supply device 32. The rear body Cb is transported to the first sewing machine 21 (step S30B).

The transfer control unit 15 moves the dough transfer device 4 to the second supply position PF2. The transport control unit 15 sucks and holds one back body Cb installed on the installation table 322 of the second dough supply device 32 on the suction surface HS of the dough transport device 4. The transport control unit 15 moves the fabric transport device 4 holding the back body Cb to the first sewing machine position PH1. The transport control unit 15 transfers the rear body Cb to the target position specified in the table 211 of the first sewing machine 21 so that the rear body Cb is held by the fabric transfer device 4 at the first sewing machine position PH1. Adjust the position of.

As described with reference to FIG. 12, the transport control unit 15 is held by the fabric transport device 4 so that the target portion of the side portion W of the rear body Cb is arranged at the first suture position PM1. Adjust the position of the body Cb. Based on the detection result of the position sensor 217, the transfer control unit 15 finely adjusts the relative position between the back body Cb held by the fabric transfer device 4 and the first stitch position PM1 at the first sewing machine position PH1.

The first sewing machine control unit 13 controls the first sewing machine 21 to sew the back body Cb sucked and held on the suction surface HS of the fabric transport device 4 and the label L supplied from the label supply device 8 ( Step S30C).

The sewing machine head 212 sutures the back body Cb and the label L while feeding the back body Cb and the label L in the sewing direction. The transfer control unit 15 moves the fabric transfer device 4 holding the rear body Cb in the sewing direction in synchronization with the stitching of the rear body Cb and the label L by the sewing machine head 212 of the first sewing machine 21. Further, the transfer control unit 15 moves the fabric transfer device 4 in the sewing direction while pressing the back body Cb against the table 211 by the fabric transfer device 4.

After the stitching between the back body Cb and the label L is completed in the first sewing machine 21, the transfer control unit 15 controls the fabric transfer device 4 to transfer the back body Cb from the first sewing machine 21 to the second sewing machine 22. (Step S40).

The transport control unit 15 moves the fabric transport device 4 holding the back body Cb to the second sewing machine position PH2. The transport control unit 15 transfers the rear body Cb to the target position specified in the table 221 of the second sewing machine 22 so that the rear body Cb is held by the fabric transfer device 4 at the second sewing machine position PH2. Adjust the position of. In the present embodiment, the transport control unit 15 controls the fabric transport device 4 to adjust the position of the rear body Cb with respect to the front body Ca installed on the table 221 of the second sewing machine 22.

The transfer control unit 15 adjusts the position of the dough transfer device 4 so that the front body Ca installed on the table 221 and the rear body Cb held by the dough transfer device 4 overlap each other on the table 221. In the present embodiment, the position of the right shoulder portion KR of the front body Ca is adjusted in step S30A before the back body Cb is transported to the table 221 by the dough transport device 4. Therefore, in the transport control unit 15, the left shoulder portion KL of the front body Ca installed on the installation surface 221S of the table 221 coincides with the left shoulder portion KL of the rear body Cb transported to the table 221 by the fabric transport device 4. By controlling the dough transfer device 4 in this way, as described with reference to FIG. 16, in the table 221 the position of the right shoulder portion KR of the front body Ca and the position of the right shoulder portion KR of the rear body Cb are set. The front body Ca and the back body Cb can be overlapped so that the positions of the left shoulder portion KL of the front body Ca and the position of the left shoulder portion KL of the back body Cb coincide with each other.

The transfer control unit 15 controls the dough transfer device 4, transfers the back body Cb held by the dough transfer device 4 to the table 221 of the second sewing machine 22, adjusts the position of the back body Cb, and then adjusts the position of the back body Cb. The suction holding of the back body Cb by the suction surface HS of the transport device 4 is released. As a result, the back body Cb is passed to the table 221 of the second sewing machine 22 and is superposed on the front body Ca. The front body Ca and the back body Cb coincide with the position of the right shoulder part KR of the front body Ca and the position of the right shoulder part KR of the back body Cb, and the position of the left shoulder part KL of the front body Ca and the back body Cb. It is superposed so that the position of the left shoulder portion KL coincides.

After the front body Ca and the back body Cb are installed on the table 221 of the second sewing machine 22 and the adsorption and holding of the back body Cb by the dough transfer device 4 is released, the second sewing machine is as described with reference to FIG. The control unit 14 fixes the left shoulder portion KL of the front body Ca and the left shoulder portion KL of the rear body Cb with the first fabric pressing member 240L (step S50).

After the left shoulder portion KL of the front body Ca and the left shoulder portion KL of the rear body Cb are fixed to the first fabric pressing member 240L, as described with reference to FIG. 7B, the transport control unit 15 is a movable member. The movable member 63 of the suction member 6 is lowered so that the lower end portion of the 63 is arranged below the suction surface HS.

The transport control unit 15 adjusts the position of the dough transport device 4 to bring the lower end portion of the movable member 63 into contact with the rear body Cb away from the suction surface HS of the dough transport device 4. The transport control unit 15 controls the robot 5 to move the movable member 63 in the XY plane in a state where the movable member 63 and the rear body Cb are in contact with each other, and adjusts the positions of the rear body Cb and the front body Ca. do.

As described with reference to FIG. 18, the transport control unit 15 moves the fabric transport device 4 in the XY plane in a state where the vicinity of the right shoulder portion KR of the fabric C and the movable member 63 are in contact with each other. The position of the right shoulder portion KR with respect to the left shoulder portion KL fixed to the first fabric holding member 240L is adjusted.

As described with reference to FIG. 19, the transport control unit 15 adjusts the position of the right shoulder portion KR with respect to the left shoulder portion KL so that the right shoulder portion KR and the left shoulder portion KL are arranged linearly. As described with reference to FIG. 20, the transport control unit 15 is right with respect to the left shoulder portion KL so that the seam line SL of the left shoulder portion KL and the seam line SR of the right shoulder portion KR are arranged on the same straight line. The position of the shoulder portion KR is adjusted (step S60).

The fabric between the right shoulder portion KR and the left shoulder portion KL is adjusted by adjusting the position of the right shoulder portion KR with respect to the left shoulder portion KL so that the right shoulder portion KR and the left shoulder portion KL are arranged in a straight line. Wrinkles may occur in at least a part of C. The transport control unit 15 can smooth out wrinkles by moving the robot 5 in the XY plane in a state where the movable member 63 and the cloth C are in contact with each other.

After the position of the right shoulder portion KR is adjusted by the movable member 63 of the fabric transport device 4, the second sewing machine control unit 14 is the front body Ca on the second fabric pressing member 240R as described with reference to FIG. The right shoulder portion KR of the body and the right shoulder portion KR of the back body Cb are fixed (step S70).

After the front body Ca and the rear body Cb are fixed by the first fabric pressing member 240L and the second fabric pressing member 240R, the second sewing machine control unit 14 controls the fabric pressing transport device 230 to control the front body Ca and the rear body. The body Cb is held by the fabric presser transfer device 230. The second sewing machine control unit 14 controls the sewing machine head 222 to sew the front body Ca and the back body Cb along the seam line SL and the seam line SR (step S80). The front body Ca and the back body Cb are sewn by the sewing machine head 222 while being moved in the sewing direction parallel to the X-axis direction.

[effect]
As described above, according to the present embodiment, the sewing system 1 includes a fabric transfer device 4 that holds the fabric C supplied from the fabric supply device 3 and conveys the fabric C to the sewing machine 2. By providing the dough transfer device 4 including the robot 5, the dough C is quickly and accurately supplied to the sewing machine 2. Therefore, the decrease in clothing productivity is suppressed.

Further, in the present embodiment, the dough transport device 4 holds the dough C from above. As a result, the dough transfer device 4 moves above each of the first supply position PF1, the second supply position PF2, the first sewing machine position PH1, and the second sewing machine position PH2, and holds the dough C from above. It can be transported quickly by releasing the holding.

Further, in the present embodiment, the first sewing machine 21 has a table 211 and a sewing machine head 212 for suturing the back body Cb installed on the table 211, and the fabric transfer device 4 has the back body Cb on the table 211. To transport to. As a result, the first sewing machine 21 can quickly perform suturing of the back body Cb conveyed to the table 211 and the label L. Further, the second sewing machine 22 has a table 221 and a sewing machine head 222 for suturing the front body Ca and the back body Cb installed on the table 221. The fabric transport device 4 has the front body Ca and the back body Cb. Transport to table 221. As a result, the second sewing machine 22 can quickly perform suturing between the front body Ca and the back body Cb transported to the table 212.

Further, in the present embodiment, the fabric transfer device 4 holds the back body Cb in the suture on the sewing machine head 212. For example, when the holding of the back body Cb by the fabric transport device 4 is released before suturing in the sewing machine head 212, a position adjustment mechanism for adjusting the relative position between the first suture position PM1 and the back body Cb is separately provided. Needs may arise. In addition, it may be necessary to secure the time required for position adjustment by the position adjustment mechanism. As a result, equipment costs may increase and clothing productivity may decrease. In the present embodiment, the back body Cb is stitched to the label L in the first sewing machine 21 while being held by the fabric transport device 4. Therefore, an increase in equipment cost and a decrease in productivity are suppressed.

Further, in the present embodiment, the sewing machine head 212 sutures while feeding the back body Cb in the sewing direction, and the fabric transport device 4 holds the back body Cb in synchronization with the suture by the sewing machine head 212 and sews in the sewing direction. Move to. As a result, suturing on the sewing machine head 212 is smoothly performed.

Further, in the present embodiment, the dough transport device 4 presses the back body Cb against the table 211. As a result, suturing in the first sewing machine 21 is smoothly performed.

Further, in the present embodiment, the fabric transport device 4 transports the back body Cb from the first sewing machine 21 to the second sewing machine 22. As a result, even when the garment is manufactured through a plurality of steps by the plurality of sewing machines 2, the fabric C is quickly and accurately supplied to each of the plurality of sewing machines 2. Therefore, the decrease in clothing productivity is suppressed.

Further, in the present embodiment, the fabric transport device 4 transports the rear body Cb from the first fabric supply device 31 to the first sewing machine 21, sutures the rear body Cb in the first sewing machine 21, and from the first sewing machine 21. In the transportation of the rear body Cb to the second sewing machine 22, the rear body Cb is continuously held. When the holding and holding of the back body Cb by the dough transport device 4 is frequently repeated, the time required for the dough transport device 4 to release the holding of the back body Cb and the time required for holding the back body Cb are reduced. It is necessary to secure it. In addition, it is necessary to adjust the position of the rear body Cb by a separately provided position adjusting mechanism each time the holding / releasing and holding of the rear body Cb are repeated. As a result, equipment costs may increase and clothing productivity may decrease. In the present embodiment, since the dough transfer device 4 continues to hold the back body Cb, the time required for the dough transfer device 4 to release the holding of the back body Cb and the time required to hold the back body Cb are omitted. can do. Therefore, the decrease in clothing productivity is suppressed.

Further, in the present embodiment, the dough transfer device 4 adjusts the position of the dough C in each of the first sewing machine 21 and the second sewing machine 22 while holding the dough C. As a result, the fabric C is accurately conveyed to the target position in each of the first sewing machine 21 and the second sewing machine 22.

Further, in the present embodiment, the dough transport device 4 has a movable member 63 which is a contact member capable of contacting the dough C, and at least a part of the dough C is in contact with the lower end portion of the movable member 63. Move the dough transfer device 4 with and adjust the position of the dough C. As a result, the position of the dough C can be adjusted with high accuracy by utilizing the high positioning accuracy of the dough transfer device 4 including the robot 5.

Further, in the present embodiment, a detection device 313 for detecting the position of the front body Ca and a detection device 323 for detecting the position of the back body Cb are provided, and the fabric transfer device 4 is a detection result and detection device of the detection device 313. Based on the detection result of 323, the position of the front body Ca and the position of the rear body Cb are adjusted. As a result, the fabric transport device 4 can transport the fabric C to the target position with high accuracy in the coordinate system defined by the sewing system 1.

Further, in the present embodiment, the detection device 313 is arranged in the first dough supply device 31, and the detection device 323 is arranged in the second dough supply device 32. Since the position of the front body Ca is detected by the first fabric supply device 31 which is the starting point of transporting the front body Ca, the fabric transport device 4 is transported from the first fabric supply device 31 which is the starting point of transporting the front body Ca. The position of the front body Ca can be adjusted with high accuracy based on the detection result of the detection device 313 up to the second sewing machine 22 which is the end point of the above. Similarly, since the position of the back body Cb is detected in the second dough supply device 32 which is the starting point of transporting the back body Cb, the dough transport device 4 is the second dough supply device which is the starting point of transporting the back body Cb. From 32 to the second sewing machine 22, which is the end point of transportation, the position of the rear body Cb can be adjusted with high accuracy based on the detection result of the detection device 323.

Further, in the present embodiment, the adjustment of the position of the dough C by the dough transfer device 4 is the adjustment of the position of the dough C with respect to the target position specified in the first sewing machine 21 and the target position specified in the second sewing machine 22. Includes adjustment of the position of the fabric C with respect to. Since the fabric C is placed at the target position defined by the sewing machine 2 with high accuracy by the fabric transport device 4, the target portion of the fabric C is sewn well. Therefore, manufacturing defects of clothing are suppressed.

Further, in the present embodiment, the second sewing machine 22 has a first fabric pressing member 240L for fixing the left shoulder portion KL of the fabric C, and the adjustment of the position of the fabric C by the fabric transport device 4 is performed with respect to the left shoulder portion KL. Includes adjustment of the position of the right shoulder portion KR of fabric C. Thereby, as described with reference to FIGS. 18 and 19, the dough transfer device 4 can be used to accurately arrange the seam line SL and the seam line SR on the same straight line.

Further, in the present embodiment, the dough transport device 4 has a suction member 6 having a suction surface HS that sucks and holds the cloth C from above, and a movable member 63 that is movably supported by the suction member 6. After the left shoulder portion KL of the dough C from which the suction holding of the suction member 6 is released is fixed to the first dough holding member 240L, the dough transfer device 4 moves the dough C away from the suction surface HS and the lower end portion of the movable member 63. The position of the right shoulder portion KR of the fabric C is adjusted by moving in the XY plane in a state of being in contact with the fabric C. As a result, the relative positions of the left shoulder portion KL and the right shoulder portion KR in the XY plane can be smoothly adjusted.

Further, in the present embodiment, the adjustment of the position of the cloth C by the cloth transport device 4 includes the adjustment of the position of the back body Cb with respect to the front body Ca installed on the table 221 of the second sewing machine 22. As a result, on the table 221 of the second sewing machine 22, the rear body Cb can be accurately superimposed on the front body Ca.

Further, in the present embodiment, the dough transfer device 4 conveys the front body Ca from the first dough supply device 31 to the second sewing machine 22 to adjust the position of the front body Ca, and then from the second dough supply device 32. The rear body Cb is transported to the second sewing machine 22 to adjust the position of the rear body Cb with respect to the front body Ca installed in the second sewing machine 22. In the present embodiment, the front body Ca and the back body Cb are sequentially transported to the second sewing machine 22 by the dough transfer device 4 including the single robot 5 and the suction member 6, and the position of the front body Ca and the back body Cb are sequentially conveyed. The position of can be adjusted accurately.

Further, in the present embodiment, the first dough supply device 31 includes an installation table 312 on which the front body Ca is installed, and the dough transfer device 4 conveys the front body Ca one by one from the installation table 312. Further, the second dough supply device 32 includes an installation table 322 on which the back body Cb is installed, and the dough transfer device 4 conveys the back body Cb one by one from the installation table 322. As a result, in the sewing machine 2, the front body Ca and the back body Cb are sewn one by one, so that the manufacturing defect of clothing is suppressed.

1 ... sewing system, 2 ... sewing machine, 3 ... fabric supply device, 4 ... fabric transfer device, 5 ... robot, 6 ... suction member, 7 ... base member, 8 ... label supply device, 9 ... label transfer device, 10 ... control Device, 11 ... front body position data acquisition unit, 12 ... rear body position data acquisition unit, 13 ... first sewing machine control unit, 14 ... second sewing machine control unit, 15 ... transfer control unit, 16 ... storage unit, 17 ... Output unit, 21 ... 1st sewing machine, 22 ... 2nd sewing machine, 31 ... 1st fabric supply device, 32 ... 2nd fabric supply device, 33 ... plate member, 33S ... top surface, 33T ... bottom surface, 34 ... support device, 35 ... base member, 36 ... spring, 37 ... hole, 51 ... arm, 60 ... main body member, 60A ... first member, 60B ... second member, 60C ... third member, 60D ... fourth member, 60E ... fifth member , 60F ... 6th member, 61 ... 1st suction member, 61A ... upper plate, 61B ... lower plate, 61C ... side plate, 62 ... second suction member, 63 ... movable member, 64 ... connector, 65 ... 1st support member , 66 ... second support member, 67 ... fixing mechanism, 68 ... fixing mechanism, 69 ... guide mechanism, 70 ... vacuum system, 71 ... connecting member, 72 ... plate member, 73 ... actuator, 81 ... first label feeder, 82 ... 2nd label supply device, 83 ... 3rd label supply device, 84 ... label accommodating member, 85 ... label transfer mechanism, 91 ... clamp mechanism, 92 ... guide mechanism, 93 ... actuator, 211 ... table, 211S ... installation surface , 212 ... Sewing machine head, 213 ... Sewing machine needle, 214 ... Drive mechanism, 215 ... First presser member, 216 ... Second presser member, 217 ... Position sensor, 221 ... Table, 221K ... Opening, 221S ... Installation surface, 222 ... Sewing machine head, 223 ... sewing machine needle, 224 ... drive mechanism, 225 ... presser member, 230 ... dough presser transfer device, 231 ... dough presser member, 232 ... arm member, 233 ... slider, 234 ... guide member, 235 ... actuator, 240 ... Fabric presser member, 240L ... First fabric presser member, 240R ... Second fabric presser member, 241 ... Support device, 241L ... First support device, 241R ... Second support device, 250 ... Fabric position adjusting device, 251 ... Plate Member, 251S ... Holding surface, 251T ... Bottom surface, 252 ... Actuator, 253 ... Suction hole, 254 ... Support member, 255 ... Base member, 256 ... Tube member, 311 ... Containment device, 312 ... Installation stand, 313 ... Detection device, 321 ... Containment device, 322 ... Installation stand, 323 ... Detection device, C ... Fabric, Ca ... Front body (first fabric), Cb ... Back body (Second fabric), HS ... Adsorption surface, HS1 ... Adsorption surface, HS2 ... Adsorption surface, K ... Shoulder part, KR ... Right shoulder part, KL ... Left shoulder part, L ... Label, L1 ... First label, L2 ... First 2 labels, L3 ... 3rd label, PF1 ... 1st supply position, PF2 ... 2nd supply position, PH1 ... 1st sewing machine position, PH2 ... 2nd sewing machine position, PM1 ... 1st stitch position, PM2 ... 2nd stitch position , SL ... seam line, SR ... seam line, VS ... space, W ... side part, WR ... right side part, WL ... left side part.

Claims (18)

With a sewing machine
A dough transfer device that holds the dough supplied from the dough supply device and conveys the dough to the sewing machine is provided.
The sewing machine has a table and a sewing machine head for sewing the fabric placed on the table.
The dough supply device has an installation table on which the dough is installed.
The dough transfer device is held by a base member arranged between the table and the installation table, an articulated robot that can move on the base member, and the articulated robot to adsorb and hold the dough. With a suction member,
The articulated robot can move the suction member to each of the supply position facing the installation table and the sewing machine position facing the table.
Sewing system. The dough transfer device holds the dough from above.
The sewing system according to claim 1. The dough transfer device transfers the dough to the table.
The sewing system according to claim 1 or 2. The fabric transfer device holds the fabric in the stitching of the sewing machine head.
The sewing system according to claim 3. The sewing machine head stitches the fabric while feeding it in the sewing direction.
The fabric transfer device holds the fabric and moves in the sewing direction in synchronization with the stitching of the sewing machine head.
The sewing system according to claim 3 or 4. The dough transfer device presses the dough against the table.
The sewing system according to any one of claims 3 to 5. The sewing machine includes a first sewing machine and a second sewing machine.
The dough transfer device transfers the dough from the first sewing machine to the second sewing machine.
The sewing system according to any one of claims 1 to 6. The dough transfer device transfers the dough from the dough supply device to the first sewing machine, sutures the first sewing machine, and conveys the dough from the first sewing machine to the second sewing machine. Keep holding,
The sewing system according to claim 7. The dough transfer device adjusts the position of the dough in the sewing machine.
The sewing system according to any one of claims 1 to 8. The dough transfer device has a contact member that can come into contact with the dough, and moves the contact member that has come into contact with at least a part of the dough to adjust the position of the dough.
The sewing system according to claim 9. Equipped with a detection device that detects the position of the fabric,
The dough transfer device adjusts the position of the dough based on the detection result of the detection device.
The sewing system according to claim 10. The detection device is arranged in the dough supply device.
The sewing system according to claim 11. The adjustment of the position of the dough includes the adjustment of the position of the dough with respect to the target position specified in the sewing machine.
The sewing system according to any one of claims 10 to 12. The sewing machine has a fabric holding member for fixing the first portion of the fabric.
The adjustment of the position of the dough includes the adjustment of the position of the second part of the dough with respect to the first part.
The sewing system according to any one of claims 10 to 13. The dough transport device has a suction member having a suction surface for sucking and holding the cloth from above, and a movable member movably supported by the suction member.
The contact member includes the movable member.
After the first portion of the dough from which the suction holding of the suction member is released is fixed to the dough holding member,
The dough transfer device moves in a state where the dough away from the suction surface and the contact member are in contact with each other to adjust the position of the second portion.
The sewing system according to claim 14. The dough contains a first dough and a second dough.
The adjustment of the position of the dough includes the adjustment of the position of the second dough with respect to the first dough installed in the sewing machine.
The sewing system according to any one of claims 9 to 15. The dough supply device includes a first dough supply device for supplying the first dough and a second dough supply device for supplying the second dough.
The dough transfer device transfers the first dough from the first dough supply device to the sewing machine, adjusts the position of the first dough, and then conveys the second dough from the second dough supply device to the sewing machine. Then, the position of the second fabric with respect to the first fabric installed in the sewing machine is adjusted.
The sewing system according to claim 16. The dough transfer device conveys the dough one by one from the installation table.
The sewing system according to any one of claims 1 to 17.

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