JP2006181391A - Thread winder and sewing machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To efficiently interchange threads with a simple structure and low cost in a sewing machine. <P>SOLUTION: A thread winder (thread winding unit 30) of a sewing machine (1) includes spool mount portions (spool pin 31 and 32) for mounting spools, and automatically winds up a thread of a spool at the spool mount portion. The thread winder is detachably mounted to the sewing machine. The thread winder is provided with a plurality of thread mount portions and includes a switching means (switch arm-holding member 60) for winding or switching the thread of the spool at any mount portion. The sewing machine (1) has a sewing machine body (1a) provided with a winding drive source (winding motor 82) for winding up the thread in the thread winder. The sewing machine body (1a) is provided with a switching drive source (switching motor 83) for the switching means in the thread winder. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a yarn winding device and a sewing machine including the yarn winding device.

When sewing with a sewing machine, for example, when forming an embroidery pattern or connecting fabrics of different colors and patterns, it is necessary to change the thread in the middle.
In a conventional household sewing machine, when changing the thread, the thread spool is completely changed by hand. In an industrial embroidery sewing machine, a number of colored yarn pieces are set, and a multicolor pattern or the like is formed while automatically changing the yarn pieces one after another.
JP 2000-325682 A JP-A-3-234288

  However, if the thread spools are manually changed like a conventional household sewing machine, there is a problem that work efficiency is poor and troublesome when many colors are used. On the other hand, if the thread is automatically replaced like an industrial sewing machine, it is excellent in terms of work efficiency, but it becomes an exchange device with a complicated structure, so it is very expensive and compared with that for household use. There is a problem that it cannot be applied to a low-priced sewing machine.

  An object of the present invention is to enable a thread to be efficiently exchanged in a sewing machine with a relatively simple structure and low cost.

In order to solve the above problems, the invention described in claim 1
Provided with a thread attachment part (thread spools 31, 32) for attaching a thread spool,
In the yarn winding device (yarn winding unit 30) of the sewing machine (1) that automatically winds the yarn of the thread spool of the yarn mounting portion,
It is characterized in that it can be detachably attached to the sewing machine.

  According to the first aspect of the present invention, when the yarn winding device is attached to the sewing machine, the yarn is automatically wound, and the yarn can be wound efficiently, and as a result, the yarn piece can be easily replaced. In addition, since it is configured to be detachable from the sewing machine, it can be attached to the sewing machine as necessary, and the yarn winding mechanism can be realized relatively easily, which is highly convenient.

The invention described in claim 2 is the yarn winding device according to claim 1,
There are multiple thread attachments,
It is characterized by comprising switching means (switching arm holding member 60) capable of switching which thread spool of the thread attachment portion is to be wound.

  According to the second aspect of the present invention, a plurality of thread attachment portions are provided, and the switching means can switch which yarn thread of the thread attachment portion of the thread attachment portion is taken up. Therefore, while sewing with the thread from one thread spool, another thread spool is mounted on the other thread mounting section, and after sewing, the former thread spool is automatically wound by the thread winding device. If this is the case, the thread from the latter thread piece can be used immediately for sewing, which is particularly useful when it is necessary to change the thread many times as in embroidery sewing.

  Here, regarding the operation of the switching means, an electric drive source such as a motor or a solenoid may be used, or a mechanically connected switching mechanism may be manually operated.

The invention according to claim 3 is a sewing machine (1) provided with the yarn winding device according to claim 1 or 2,
A winding drive source (winding motor 82) for winding the yarn in the yarn winding device is provided in the sewing machine body (1a).

  According to the third aspect of the present invention, it is possible to obtain the same effect as that of the first or second aspect of the invention, and the drive source for the winding operation of the yarn winding device is the sewing machine body. The yarn winding device itself may have a simple configuration.

The invention according to claim 4 is a sewing machine (1) provided with the yarn winding device according to claim 2,
A switching drive source (switching motor 83) of switching means in the yarn winding device is provided in the sewing machine body (1a).

  According to the invention described in claim 4, since the same effect as that of the invention described in claim 2 can be obtained, the drive source for the switching operation is provided in the sewing machine body. The yarn winding device itself may have a simple configuration.

  In each of claims 3 and 4, the drive source provided in the sewing machine main body may be originally used as some drive source, or may be dedicated for winding or switching.

  According to the first aspect of the present invention, when the yarn winding device is attached to the sewing machine, the yarn is automatically wound, and the yarn can be wound efficiently, and as a result, the yarn piece can be easily replaced. In addition, since it is configured to be detachable from the sewing machine, it can be attached to the sewing machine as necessary, and the yarn winding mechanism can be realized relatively easily, which is highly convenient.

  According to the second aspect of the present invention, a plurality of thread attachment portions are provided, and the switching means can switch which yarn thread of the thread attachment portion of the thread attachment portion is taken up. Therefore, while sewing with the thread from one thread spool, another thread spool is mounted on the other thread mounting section, and after sewing, the former thread spool is automatically wound by the thread winding device. If this is the case, the thread from the latter thread piece can be used immediately for sewing, which is particularly useful when it is necessary to change the thread many times as in embroidery sewing.

  According to the third aspect of the present invention, it is possible to obtain the same effect as that of the first or second aspect of the invention, and the drive source for the winding operation of the yarn winding device is the sewing machine body. The yarn winding device itself may have a simple configuration.

  According to the invention described in claim 4, since the same effect as that of the invention described in claim 2 can be obtained, the drive source for the switching operation is provided in the sewing machine body. The yarn winding device itself may have a simple configuration.

Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the drawings.
FIG. 1 shows a sewing machine 1 as an example to which the present invention is applied. The sewing machine 1 is a household sewing machine with an embroidery mode, and an embroidery device 5 and a thread winding unit 30 (see FIG. 2) are detachably provided on a sewing machine body 1a. The sewing machine main body 1 a includes a bed portion 2, a vertical trunk portion 3 standing on the bed portion 2, and an arm portion 4 extending from the vertical trunk portion 3 so as to be parallel to the bed portion 2.
In the sewing machine 1, when the embroidery device 5 is detached under the control of the control unit 81 (FIG. 9), which will be described later, the sewing machine 1 is in a main body mode in which a main sewing or a pattern sewing of a predetermined pattern can be performed, When this is done, this is detected by the embroidery device detection sensor 5a (FIG. 9) and the embroidery mode is switched.

As shown in FIGS. 1 and 2, a thread spool bar 10 into which a thread spool can be fitted is provided at the rear of the upper surface of the sewing machine main body 1a, and thread spool bars 31 and 32 into which the thread clamp is fitted are provided on the back panel 1b. The provided bobbin unit 30 is attached. Upper thread is supplied from the thread spool attached to the thread spool rod 10 and the thread winding unit 30. The sewing machine 1 is provided with an automatic threading mechanism for automatically passing the upper thread through the sewing needle 7. The upper thread from the thread winding unit 30 or the thread spool bar 10 is hung at a predetermined position on the arm unit 4. If so, the thread is automatically passed through the sewing needle 7 at a predetermined timing. Since the thread spool 10 is not the gist of the present invention, only the upper thread from the thread winding unit 30 will be described in the following description.
A thread guide 17 is fixed at the center of the upper surface of the arm portion 4. In the vicinity of the yarn guide 17 and in the arm portion 4, a base tension portion 16 that fixes a constant tension to the upper thread t is fixed. The base tension portion 16 is closed during sewing, automatic thread trimming, and automatic threading to apply tension to the thread, and is opened when the thread winding unit 30 winds the thread.

  Further, an upper thread state detection sensor 20 is provided in the vicinity of the base tension portion 16. The upper thread state detection sensor 20 detects the tension of the upper thread during the yarn winding process, and is a thread detection means of the present invention. Details are shown in FIG. The upper thread state detection sensor 20 includes a photo interrupter 21, a shielding plate 22, a shielding plate operating member 23, and a torsion coil spring 24.

The photo interrupter 21 is formed in a U-shaped cross section by a light emitting portion and a light receiving portion (not shown) provided so as to face each other, and a shielding plate 22 formed in a substantially key shape between the light emitting portion and the light receiving portion. The one end 22a side faces so that it can appear and disappear. A shield plate actuating member 23 whose tip is bent in a U shape is fixed to the other end 22b of the shield plate 22. The upper thread from the base tension portion 16 is attached to the shield plate actuating member 23 as indicated by an arrow. Passed through.
A torsion coil spring 24 is attached around the bent portion of the shielding plate 22, and one end of the torsion coil spring 24 is hung on the sewing machine frame and the other end is hung on the shielding plate 22. As a result, if the upper thread is not loosened or the upper thread is not passed, the one end 22a of the shielding plate 22 faces between the light emitting part and the light receiving part by the urging force of the torsion coil spring 24 (solid line in FIG. 3), and the photo The interrupter outputs an off signal to the CPU 81a. When the upper thread passed through the shielding plate actuating member 23 is in tension, the shielding plate actuating member 23 is pushed downward by the upper thread, so that the shielding plate 22 resists the urging force of the torsion coil spring 24. Rotating clockwise, the photo interrupter outputs an ON signal (virtual line in FIG. 3).

  Inside the arm portion 4, there is provided a feeding roller 11 that feeds the upper thread supplied from the thread winding unit 30 in the direction of the sewing needle 7. The feeding roller 11 includes a driving roller 11a that is rotationally driven by a feeding motor 12 that is a stepping motor, and a driven roller 11b that rotates with the rotation of the driving roller 11a in contact with the driving roller 11a. The driven roller 11b is mechanically interlocked with the operation of the presser foot lever 8 (FIG. 1) and contacts and separates from the driving roller 11a. When the presser foot lever 8 is operated in the direction of lowering the presser foot 9, it comes into contact with the drive roller 11 a, and when it is operated in the reverse direction, it is separated from the drive roller 11 a.

The feeding motor 12 operates intermittently rather than continuously during sewing, whereby the feeding roller 11 intermittently feeds the upper thread by a predetermined amount. Further, the feeding motor 12 operates intermittently in the direction opposite to that during sewing in the yarn winding process, and the feeding roller 11 intermittently sends the upper thread to the yarn spool side. Therefore, in the yarn winding process, the yarn is loosened every time the feeding roller 11 feeds a predetermined amount of yarn, and the tensioning is repeated when the yarn is wound by a winding motor 82 described later, and the upper yarn state detection sensor 20 is turned on. The signal (the state where the yarn is tensioned) and the off signal (the state where the yarn is loosened) are repeated.
The feeding roller 11 and the feeding motor 12 constitute the feeding means of the present invention.
Since the rotation transmission mechanism from the feeding motor 12 to the feeding roller 11 and the interlocking mechanism between the presser foot lever 8 and the driven roller 11b are well known in the art, the details are omitted.

The upper thread t supplied from the thread winding unit 30 is passed through the thread guide 17, and is clamped by the feeding roller 11 through the base tension unit 16 and the upper thread state detection sensor 20.
An upper thread guide 13 that guides the upper thread in a predetermined direction is provided inside the arm portion 1 and below the feeding roller 11. The upper thread t fed from the feeding roller 11 is passed through the upper thread guide 13 and the thread take-up spring 14 and the balance 15 provided outside the cover of the arm portion 4.
A needle bar (not shown) is provided on the arm portion 4 so as to be movable up and down. A sewing needle 7 is fixed to a lower end portion of the arm portion 4, and the upper thread t is guided to the sewing needle 7 through a balance 15.
A presser foot 6 is fixed in the vicinity of the sewing needle 7. The presser foot 6 can be moved up and down by operating the presser foot lever 8 with a conventionally known structure.

As shown in FIG. 2, a thread winding unit 30 as a thread winding mechanism and a thread winding device of the present invention is detachably attached to the back panel 1b of the sewing machine body 1a. This thread winding unit 30 is provided with two thread spools (thread attaching portions) 31 and 32 to which a thread spool can be attached, and supplies the upper thread from this, and winds the thread from the sewing needle 7 after sewing. It is. Hereinafter, the yarn piece set on the spool pin 31 may also be called the yarn piece A, and the yarn piece set on the spool pin 32 may be called the yarn piece B.
The bobbin winding unit 30 includes a support box 41 that supports the thread spools 31 and 32. From the mounting surface 41a of the support box 41, an insertion protrusion 42 formed with a recess 42b and auxiliary protrusions 41b and 41b formed so that the tip bends downward protrude. On the surface 41c of the support box 41, an operation lever 42a substantially integrated with the insertion protrusion 42 is provided, and the operation lever 42a and the insertion protrusion 42 are rotatable around a fulcrum (not shown) between them. It has become. Further, the operation lever 42a and the insertion protrusion 42 are urged by a lever spring 43 shown in FIG. 4 so that the tip of the insertion protrusion 42 is directed upward.

The thread winding unit 30 is attached to the sewing machine body 1a as follows. The insertion protrusion 42 is inserted into the insertion hole 1 d formed in the back panel 1 b while rotating downward while resisting the biasing force of the lever spring 43. Then, the insertion protrusion 42 is locked by the sewing machine frame around the insertion hole 1d in the recess 42b while rotating upward by the biasing force of the lever spring 43. At the same time, the auxiliary protrusions 41b and 41b are engaged with the auxiliary holes 1e and 1e formed side by side above the insertion hole 1d.
When detaching the support box 41, the operation lever 42a may be directed upward to raise the support box 41 while lowering the insertion protrusion 42 downward.
The sewing machine body 1a is provided with a unit detection sensor 87 (FIG. 9), and the rear panel 1b is provided with a sensor hole 9a. The attachment surface 41a of the support box 41 is provided with a sensor protrusion 66 that can be engaged with the sensor hole 9a. When the bobbin winding unit 30 is attached to the back panel 1b, the sensor protrusion 66 enters the sensor hole 9a. A unit detection signal is output from the unit detection sensor 87 to the control unit 81.

As shown in FIGS. 4 and 5, the support box 41 includes a first winding unit 50 and a second winding unit 51 that support the spool pins 31 and 32 and perform the winding operation of the yarn. It has been. Since the 1st winding part 50 and the 2nd winding part 51 are substantially the same structures, the same code | symbol is attached | subjected about the same member. Moreover, in FIG. 4, the 1st winding part 50 is shown in the cross section for convenience. The first winding unit 50 and the second winding unit 51 are fixed inside the support box 41 and supported by a mounting plate 52 having an upper base plate 52a and a lower base plate 52b.
A bearing 54 is provided at the lower end of the first winding unit 50 (second winding unit 51), and this bearing 54 is screwed to the lower base plate 52b with screws 53. A hollow thin rod-like thread stand 31 (32) is fitted to and supported by the bearing 54.

On the bearing 54, there is provided a take-up gear member 55 in which the spool pin 31 (32) passes through the center and a gear 55a is formed around it. On the upper surface of the winding gear member 55, a lower connection portion 55b made of a plurality of teeth protruding upward is formed. A gap is formed inside the take-up gear member 55 in a ring shape, and a lower portion of the first compression spring 58 is attached thereto.
Above the winding gear member 55, a cylindrical inner rotating body 56c is provided so as to surround the spool pin 31 (32). The inner rotating body 56c has an inner diameter that increases in the middle, and the second compression spring 34 is loaded into a gap between the inner rotating body 56c and the spool pin 31 (32) formed thereby. The lower end portion of the second compression spring 34 is supported by the inner rotating body 56c.
A thread spool plate 33 for receiving the lower end portion of the yarn spool is attached to the upper portion of the spool pin 31 (32) so as to be slidable up and down, and the upper end portion of the second compression spring 34 is attached to the lower surface portion of the yarn spool tray 33. It is in contact. Thereby, the yarn spool tray 33 is urged upward by the second compression spring 34.

A locking groove 31a (32a) is formed along the circumferential direction at the tip of the spool pin 31 (32) in order to attach the cap 38 shown in FIG. As shown in FIG. 8, when the thread spool A is set on the thread spool 31, the thread spool 31 is inserted into the vertical hole at the center of the thread spool A, and the thread spool against the urging force of the second compression spring 34. Push in the pan 33 and insert the cap 38 from above. The same applies to thread spool B.
When the yarn spool is set in this way, the yarn clamp is always urged upward by the second compression spring 34, and the upper surface of the yarn clamp is in contact with the cap 38.

  The upper end portion of the inner rotating body 56c is formed with a larger inner diameter, and as shown in FIGS. 2 and 4, protrudes upward from the support box 41 and faces two yarn piece walls facing each other so as to surround the yarn piece It continues to 56a, 56b. As shown in FIG. 2, the yarn spool walls 56a and 56b are each formed in a triangular shape, and have triangular openings 56aa and 56bb on the inside.

A cylindrical outer rotating body 57 is fitted on the outer side of the inner rotating body 56c. The outer rotating body 57 is supported by the upper base plate 52a. As shown in FIG. 5, the auxiliary protrusion 41b is provided on the upper base plate 52a.
A flange 57a is formed in the lower portion of the outer rotating body 57 along the circumferential direction, and an upper connection portion 57b composed of a plurality of teeth is formed on the lower surface of the flange 57a so as to correspond to the lower connection portion 55b. Yes. The lower connecting portion 55b and the upper connecting portion 57b constitute a meshing clutch.
The upper end portion of the first compression spring 58 is pressed further inside the upper connection portion 57b of the flange 57a.
The switching pins of the first switching arm 61 and the second switching arm 62 described later are always in contact with the upper surface of the flange 57a. The flange 57a is driven downward against the force of the first compression spring 58 by the first switching arm 61 and the second switching arm 62, so that the lower connecting portion 55b and the upper connecting portion 57b are engaged with each other. Yes. Here, for convenience, the first thread winding portion 50 side is referred to as a clutch M, and the second thread winding portion 51 side is referred to as a clutch N. 4 shows only the switching pin 62a of the second switching arm 62, the same applies to the switching pin of the first switching arm 61.

A screw hole 57c is formed in a part of the outer rotator 57, and a long groove (not shown) is formed at a position corresponding to the screw hole 57c of the inner rotator 56c. A leg portion 35c of a bail actuating portion 35, which will be described later, is inserted into the groove and fixed by a bail fixing screw 59. When the flange 57a of the outer rotator 57 is driven downward by the first switching arm 61 (second switching arm 62), the bale actuating member 35, the inner rotator 56c, and the thread spool walls 56a and 56b are moved together with the outer rotator 57. Will descend.
Further, the bail fixing screw 59 faces the groove of the inner rotating body 56c while penetrating the outer rotating body 57, so that the inner rotating body 56c and the thread spool walls 56a, 56b are accompanied with the rotation of the outer rotating body 57. The bail operating member 35 and the bail 36 are rotated together.

As shown in FIGS. 2 and 4, the bail operating portion 35 faces the opening 56aa of the yarn spool wall 56a, bends further outward, and is formed at a height exceeding the tip of the yarn spool wall 56a. A laterally long lateral hole 35 b is formed at the tip of the bail operating portion 35.
The semi-circular bale 36 is provided above the yarn spool walls 56a and 56b, and guides the yarn when winding the yarn.
One end 36b of the bail 36 is attached to the upper edge of the yarn spool wall 56b so as to be freely rotatable. The end 36b is formed with a bent portion 36c bent downward in a U shape as shown in FIG. 7A in a state where the bail 36 is substantially standing (FIG. 4).

On the other hand, in the vicinity of the other end portion 36a of the bail 36, a bail attachment member 37 for attaching the end portion 36a is rotatably attached to the upper edge portion of the yarn spool wall 56a by a screw 37a. Yes. An end portion 36a is attached to a portion of the bail attachment member 37 at a predetermined distance from the screw 37a.
A protruding pin 37 b that protrudes outward is provided on the upper portion of the bail mounting member 37, and the protruding pin 37 b is engaged with the lateral hole 35 b of the bail operating member 35. Therefore, when the bail actuating member 35 moves up and down, the bail mounting member 37 is guided by the projecting pin 37b and rotates around the screw 37a, and at the same time, the bail 36 rotates around the screw 37a along the phantom line in FIG. Tilt sideways as shown. When the direction of the bail 36 changes in this way, the bent portion 36c of the opposite end portion 36b becomes sideways as shown in FIG. 7B.

  When turned sideways as shown in FIG. 7 (b), the bent portion 36c captures the upper thread t toward the yarn hooking body 70, which will be described later, and at the substantially central portion in the height direction of the yarn spool A (B). To position. At the time of winding, the bent portion 36c rotates with respect to the yarn spool A (B) in the direction of the arrow in FIG. That is, the bent portion 36c of the bail 36 is surely wound around the yarn spool A (B) while the angle of the upper thread t with respect to the yarn spool A (B) is regulated.

  Above the support box 41, as shown in FIGS. 2 and 8, a horizontally long rod-like thread hook 70 supported by a support rod 73 is provided. The thread hook 70 is for hooking a thread from the thread spool set on each of the thread spools 31 and 32, and a first thread hook 71 for threading the thread of the thread spool A and a thread of the thread spool B And a second thread hook portion 74. As shown in an enlarged view in FIG. 8, the first thread hook portion 71 includes a main portion 71c and a leaf spring 72 fixed to the main portion 71c and having a recess 72a. The operator guides the yarn from the thread spool A by the hand between the main portion 71c and the leaf spring 72 and hooks it on the recess 72a toward the sewing needle 7. The same applies to the second thread hook portion 74.

  As shown in FIG. 4, a switching arm holding member (switching means) 60 having a first switching arm 61 and a second switching arm 62 on the left and right is attached to the center of the mounting plate 52 so as to be rotatable around a pin 60a. It has been. The switching arm holding member 60 is formed with an extending portion 63 extending upward from the central portion thereof, and a switching operation pin 64 (FIGS. 2 and 5) so as to protrude from the support box 41 to the extending portion 63. Is fixed.

The switching operation pin 64 is inserted into a substantially triangular switching opening 9b formed in the back panel 1b when the bobbin winding unit 30 is attached to the sewing machine body 1a. Inside the switching opening 9b, there is provided a swinging member (not shown) that swings left and right by a switching motor (switching drive source) 83 (FIG. 9) made of a stepping motor. The tip of the switching operation pin 64 is fixed to the swinging member, and the switching operation pin 64 swings left and right by a predetermined angle around a predetermined origin position by swinging the swinging member. The pin 60a is turned around.
In addition, as a rocking | fluctuation mechanism of a rocking | fluctuating member, what is necessary is just to utilize the structure by a sun gear and a planetary gear, for example. In addition, the swing mechanism is provided with a switching origin detection sensor 89 that detects that it is at the origin position.

When the switching operation pin 64 moves to the right side in FIG. 4 by the rotation of the switching motor 83 in a predetermined direction, the switching pin at the tip of the switching arm 61 moves the flange 57a of the outer rotating body 57 of the first winding unit 50 downward. The clutch M is engaged.
When the switching motor 83 rotates in the reverse direction, the switching operation pin 64 moves to the left in FIG. 4 and the switching pin 62a at the tip of the switching arm 62 pushes the flange 57a of the outer rotating body of the second winding unit 51 downward. The clutch M is engaged.

A winding motor 82 (FIG. 9), which is a winding drive source, is a stepping motor, and is built inside the back panel 1b of the sewing machine body 1a. An intermediate gear 18 to which the rotation of the output shaft is transmitted is provided inside the gear hole 1c formed in the back panel 1b.
On the other hand, a winding transmission body 45 formed in a predetermined shape is projected from below the attachment surface 41 a of the support box 41 of the bobbin winding unit 30 so as to match the tip of the intermediate gear 18. As shown in FIG. 6, the winding transmission body 45 is slidably fitted to the winding shaft 46. However, an E-ring 46 a is fixed to the end portion of the winding shaft 46 so as not to be detached from the winding shaft 46.
The winding shaft 46 is fixed to the mounting plate 52, and a winding worm 44 is fitted at the other end. One end of the winding worm 44 abuts on the mounting plate 52, and an E-ring 44a is fitted to the other end so that it cannot be removed.

A winding spring 47 is provided between the winding transmission body 45 and the winding worm 44. The winding spring 47 is hung on each of the winding transmission body 45 and the winding worm 44, and is attached in a direction to keep them away from each other. It is fast.
When the support box 41 is attached to the sewing machine main body 1a as described above, when the winding transmission body 45 is fitted into the gear hole 1c, the winding transmission body 45 is pushed by the tip of the intermediate gear 18, and the winding worm Although it slides to the 44 side, it matches the predetermined shape of the tip of the intermediate gear 18 while being pushed back by the winding spring 47. Accordingly, when the winding motor 82 is operated, the rotation of the intermediate gear 18 is transmitted to the winding transmission body 45, and the winding worm 44 is rotated via the winding spring 47.

  The winding worm 44 meshes with the gear 55 a of the winding gear member 55 of the second winding unit 51. A timing belt 65 is stretched around the lower ends of the winding gear members 55 of the first winding unit 50 and the second winding unit 51. Therefore, when the winding worm 44 rotates as described above, both the winding gear members 55 of the first winding unit 50 and the second winding unit 51 rotate. However, during the winding operation, the rotation of the winding gear member 55 is transmitted to the upper structure such as the outer rotating body 57 only in one winding portion where the clutch structure is formed by the switching arm 60.

FIG. 9 shows a control circuit 80 of the sewing machine 1. The control circuit 80 includes a control unit 81. For the control unit 81, drive sources such as a feeding motor 12, a winding motor 82, and a switching motor 83, an upper thread state detection sensor 20, and an embroidery device detection sensor 5a. The unit detection sensor 87, the presser foot lowering detection sensor 88, the switching origin detection sensor 89, and other sensors, the operation panel 90, and the like are connected. FIG. 9 shows only the configuration necessary for the present invention, and the control circuit 80 includes other drive sources and sensors.
The control unit 81 includes a CPU (Central Processing Unit) 81a, a RAM (Random Access Memory) 81b, and a ROM (Read
In addition to the (Only Memory) 81c, it comprises an input / output interface and the like.
The ROM 81 c stores control programs and control data for various operations in the sewing machine 1. The RAM 81b stores sewing data including needle entry data, various detection data, calculation results, and the like.

The CPU 81a controls a series of sewing operations including a thread winding process by driving each drive source such as a motor based on signals from various sensors while using the RAM 81b as a work area in accordance with a control program and control data in the ROM 81c. In addition, display control of the operation panel 70 is also performed.
Specifically, when a detection signal indicating that the embroidery device 5 is set is output from the embroidery device detection sensor 5a, the entire sewing machine 1 is set to the embroidery mode, and otherwise, the main body mode is set.

  When the bobbin winding unit 30 is attached and a unit detection signal is received from the unit detection sensor 87, the feeding motor 12, the switching motor 83, and the winding motor 82 are driven in accordance with an instruction from the operation panel 90, and the upper thread The yarn winding process is performed while detecting the signal from the state detection sensor 20. That is, the CPU 81a is a winding control unit in the present invention. In the yarn winding process, the CPU 81a grasps the yarn winding amount by measuring the rotation amount of the winding motor 82 at a counter provided in the RAM 81b. Hereinafter, this counter is referred to as a winding amount measurement counter.

  At the time of winding, the yarn is intermittently fed by the feeding motor 12, while the winding motor 82 continuously winds the yarn, and as a result, the yarn repeats tension and relaxation, and the sensor 20 is turned on / off. Repeat off. The CPU 81a controls the yarn winding process while grasping the relationship between the on / off state of the sensor 20 and the counter value (the amount wound) by the winding amount measurement counter.

As shown in FIG. 1, an operation panel 90 is provided on the front surface of the sewing machine body. The operation panel 90 is, for example, a touch panel type formed of a liquid crystal display panel, and necessary operation buttons are displayed on the display screen together with predetermined information.
As described above, the sewing machine 1 is in the normal main body mode, and when the embroidery device 5 is set, the embroidery mode is automatically set by the detection of the embroidery device detection sensor 5a. When the yarn winding unit 30 is attached, the yarn is automatically wound by the detection of the unit detection sensor 87. On the operation panel 90, the display content changes according to the mode difference and possible operations.

FIG. 10 shows an example of a screen displayed on the operation panel 90. FIG. 10A shows a part of a work screen 91 displayed after sewing or the like when the bobbin winding unit 30 is attached. At the bottom of the screen 91, a thread change button 91a for manually specifying automatic thread winding by the thread winding unit 30 is provided.
When this thread change button 91a is operated, a selection screen 92 shown in FIG. 10B is displayed. The selection screen 92 is provided with a thread change support button 92a, an A button 92b, and a B button 92c. The A button 92b is for winding the thread of the thread spool A, and the B button 92c is for winding the thread of the thread spool B.

  When performing the thread change, for example, when the thread of the thread spool A is passed through the sewing needle 7 and it is desired to switch to the thread of the thread spool B, first, the thread of the thread spool B is a predetermined for automatic threading. It is hung on the part of. Then, the thread change support button 92a is operated, and then the A button 92b is touched. Thereby, the yarn winding unit 30 winds the yarn of the yarn spool A by a predetermined operation described later. After the winding is completed, the thread of the thread spool B is passed through the sewing needle 7 by the automatic threading mechanism.

  When the thread change is performed, the feeding roller 12 is interlocked with the presser foot 6 as described above. Therefore, if the thread change support button 72a is operated in a state in which the presser foot 6 is not lowered, “the presser foot is changed”. Please let me know "message is displayed.

The display screens of FIGS. 10A and 10B are displayed in either the main body mode or the embroidery mode.
Further, when the bobbin winding unit 30 is attached in the embroidery mode, as shown in FIG. 10C, the reservation function for thread change can be selected on the editing screen 73 for performing various editing operations of the embroidery pattern. it can. The editing screen 73 illustrated here is for a flower pattern formed by sewing “(1) stem”, “(2) leaf”, and “(3) petal” in order. But it can be displayed.

The edit screen 73 is provided with an A reservation button 93a, a B reservation button 93b, and a reservation prohibition button 93c. For example, when the first “stem” is being sewn using the thread from the thread spool B, the A reservation button 93a is pressed. Thus, after sewing the “stem”, the thread of the thread spool B is automatically wound and then automatically threaded by the thread spool A without performing the operations shown in FIGS. 10 (a) and 10 (b). . On the other hand, if the B reservation button 93b is operated, the yarn spool A is automatically wound and then the yarn spool B is automatically threaded.
If the reservation prohibit button 73c is pressed, the thread is not automatically wound or threaded after the sewing is completed. In this case, the screens shown in FIGS. 10A and 10B may be displayed after sewing.

In modes other than the embroidery mode, the A reservation button 93a, the B reservation button 93b, and the reservation prohibition button 93c are not displayed. Alternatively, these buttons are displayed even in modes other than the embroidery mode, but an error may be displayed when the A reservation button 93a and the B reservation button 93b are operated.
Further, regardless of the main body mode or the embroidery mode, when the thread winding unit 30 is not attached, a button for instructing an operation related to the thread winding unit 30 shown in FIG. 10 is operated based on a signal from the unit detection sensor 87. Even in this case, an error display or a message that “the bobbin winding unit 30 is not installed” is displayed.

The operation during the yarn winding process by the yarn winding unit 30 of the sewing machine 1 having the above configuration will be described.
When an automatic bobbin winding operation is instructed via the A button 92b, B button 92c, or the A reservation button 93a, B reservation button 93b in FIG. 10, the sewing machine 1 performs the following mechanical control under the control of the CPU 81a. To work.
The thread spool A and the thread spool B are set in the first winding section 50 and the second winding section 51, respectively, and sewing is performed with the thread of the thread spool A. Then, the thread trimming is finished, and the presser foot 6 is lowered. That is, the feeding roller 11 is closed. The yarn of the yarn piece A is in a state of being passed over the first yarn hooking portion 71 of the yarn hooking body 70 and passing through the sewing needle 7. The yarn of the yarn piece B is passed through the second yarn hooking portion 72. It is assumed that it is hung and is hung at a predetermined position for automatic threading. Hereinafter, this state is referred to as “winding initial state”.

First, the feeding motor 12 is driven in the direction opposite to that during sewing, and the thread on the sewing needle 7 side is pulled. This operation is performed intermittently during winding.
Then, the winding motor 82 starts rotating, and the winding gear member 55 of the second winding unit 51 rotates via the intermediate gear 18, the winding transmission body 45, and the winding worm 44, and then via the timing belt 65. Thus, the winding gear member 55 of the first winding unit 50 also rotates. The winding motor 82 operates continuously during winding.

  Next, based on a signal from the switching origin detection sensor 89, the switching motor 83 rotates by a predetermined angle and stops. With this operation, when the switching operation pin 64 moves to the right side in FIG. 4, it is driven by the switching pin of the switching arm 61 on the first winding portion 50 side, and the upper connection portion 57 b of the flange 57 a of the outer rotating body 57. And the lower connecting portion 55b of the take-up gear member 55, that is, the clutch M is engaged. Thereby, the rotation of the winding motor 82 is transmitted, and the outer rotating body 57, the inner rotating body 56c, the thread spool walls 56a and 56b, the bail operating unit 35, and the bail 36 on the first winding unit 50 side rotate together. At the same time, the bail actuating portion 35 is also lowered by the lowering of the outer rotating body 57, the bail 36 is collapsed and the bent portion 36c is turned sideways, and the upper thread is captured by the bent portion 36c as shown in FIG. Wound around A.

Finally, in a state where the yarn end hangs between the yarn spool A and the sensor 20, the winding motor 82 and the feeding motor 12 are stopped, the switching motor 83 is driven again, and the winding motor 82 is returned to the origin position to complete the winding. Next, automatic threading is performed on the thread spool B.
When winding the upper thread of the thread spool B, the switching pin 62a is driven by the rotation of the switching motor 83, and the thread is similarly wound on the second winding unit 51 side.
As described above, the winding motor 82 is rotated first, and then the switching motor 83 is rotated because the lower connection portion 57c and the upper connection portion 55b are rotated more than in the stopped state. This is because the engagement of the clutch structure is easy.

Next, FIGS. 11 and 12 show a flowchart of the yarn winding process performed under the control of the CPU 81a.
The CPU 81a monitors whether the yarn winding process is normally proceeding based on the signal from the upper thread state detection sensor 20, and also determines the winding amount obtained from the rotation amount of the winding motor 82 and the like of the feeding motor 12. The upper thread is wound and stopped while calculating a quantitative relationship with the feed amount. The following description will be made assuming that the upper thread of the thread spool A is taken up.

This flow starts from the initial winding state, the yarn from the yarn spool A to the feeding roller 11 is stretched, and the upper yarn state detection sensor 20 outputs an ON signal.
First, in step S1, it is confirmed that the switching motor 83 is at the origin position, that is, the switching operation pin 64 is positioned at the center. Next, in step S <b> 2, the feeding motor 12 is stopped after being driven, and a predetermined amount of yarn is rewound by the feeding roller 11. As a result, the upper thread is drawn by hand toward the yarn spool A in advance, so that when the bail 36 is tilted sideways and the thread is captured by the operation of a switching motor 83 described later, no load is applied to the thread.
In step S3, it is determined whether or not the sensor remains on, that is, whether or not the upper thread state detection sensor 20 is turned off due to the yarn being fed and loosened in step S2. If it remains on, the yarn is not supplied to the yarn spool A due to an abnormality such as yarn entanglement, so an error is displayed in step S4. If it is determined in step S3 that it is off, it is normal and the process proceeds to step S5.

In step S5, the winding motor 82 starts to rotate. Next, in step S6, the switching motor 83 is rotated in a predetermined direction by a predetermined angle, the switching arm 61 is driven to engage the clutch M of the first winding unit 50, and the outer rotating body 57, the thread spool walls 56a, 56b and the like are rotated. Winding is started while guiding the yarn to wind around the substantially central portion in the height direction of the yarn spool A by the operation of the bail 36.
Next, in step S 7, the winding amount measurement counter (MKCOUNT) is reset to “0”, and the winding amount based on the rotation of the winding motor 82 is measured. Next, in step S8, it is determined whether the sensor 20 is turned on when the yarn that has been wound up in step S6 is tensioned again. If not, in step S9, it is determined whether or not the MKCOUNT value has exceeded a predetermined limit value (for example, 8000, the number is the number of steps of the winding motor 82). If it does not exceed, the process returns to step S8, and if it exceeds, the thread remains loose and will not be wound up normally, so an error is displayed in step S10.

If the sensor is turned on in step S8, the process proceeds to step S11 where the MKCOUNT value is set to 0 again and the winding amount is started to be measured.
Next, in step S12, the feeding motor 12 is driven and stopped, and a predetermined amount of yarn is supplied to the yarn spool A side, whereby the sensor is turned off. This is because the yarn supply speed by the feeding motor 12 is faster than the winding speed by the winding motor 82.
Next, in step S13, it is determined whether the sensor 20 is turned on by supplying the yarn in step S12. If it is determined in step S13 that the signal does not turn on, it is determined in step S14 whether or not the MKCOUNT value exceeds a predetermined limit value (for example, 8000). If it does not exceed, the process returns to step S13, and if it exceeds, it means that the yarn has not been wound up normally due to thread breakage or the like, so an error display is performed in step S15.

If it is determined in step S13 that the sensor 20 has been turned on, the process proceeds to step S16, where the winding amount started from step S11 is read as the “reference winding amount”.
Next, in step S17, the reference winding amount in step S16 is read a predetermined number of times, and it is determined whether a final determined value has been obtained. If step S16 has been read only once, the process returns to step S11. If the reading in step S16 is performed a predetermined number of times (for example, twice), the determined value of the reference winding amount is obtained therefrom. As a calculation method, an average value or an experimental optimum value may be used. As described above, the measurement from step S7 corresponding to the first time is discarded, and then the reference winding amount (the winding amount corresponding to one feeding) is obtained for a plurality of times. This is because the values are different in numbers, and there is a slight difference in each time, so that it is more accurate to discard the first data and then calculate from a plurality of measurement results.

Next, in step S18, the “end winding amount” is obtained and read as the subsequent winding amount. This value is obtained by multiplying the reference winding amount obtained in step S17 by a predetermined value n. The n value is determined by the structure of the sewing machine 1 and is, for example, “6”. This end winding amount is a portion obtained by removing the final winding amount (remaining yarn amount) from the yarn length to be wound in the subsequent step.
Next, in step S19 in FIG. 12, the feeding motor 12 is fed with the rewinding thread, and the process proceeds to step S20. In step S19, it is determined whether or not the sensor remains on. If it remains on, it is abnormal such that the thread is caught and tensioned, so an error is displayed in step S21.

If it is determined in step S20 that the sensor is off, the process proceeds to step S22, the winding amount measurement counter is reset, MKCOUNT is set to “0”, and whether the sensor 20 is turned on by winding the yarn in step S23. To determine. If the sensor 20 remains off in step S23, the process proceeds to step S24, and it is determined whether or not the MKCOUNT value is smaller than the total count corresponding to the terminal winding amount obtained in step S18. If it is smaller, the process returns to step S23. If it is larger, that is, if it is determined that the end winding amount has been wound, the process proceeds to step S25.
If the sensor is turned on in step S23, the process returns to step S19. That is, the yarn is wound up while repeating Step S19 to Step S24 until the length that exceeds the end winding amount is wound.

In step S25, the MKCOUNT value is set to “0” again, and a predetermined remaining yarn amount is calculated in step S26. The remaining yarn amount is obtained by “reference winding amount × m”, and the m value is determined in terms of the structure. Next, in step S27, it is determined whether or not the MKCOUNT value is less than the remaining yarn amount. If it is less, this determination is repeated, and if the value exceeds the remaining yarn amount, the process proceeds to step S28. In step S28, the winding motor 82 is stopped, and the winding is completed with the yarn end remaining between the sensor 20 and the yarn spool A.
Next, in step S29, the switching motor 83 is driven by a predetermined angle, the switching operation pin 64 is returned to the origin, and this flow is finished.

According to the sewing machine 1 provided with the above-described yarn winding unit 30 and the yarn winding method in the sewing machine 1, the yarn is automatically used using the feeding means including the feeding roller 11 and the feeding motor 12 under the control of the CPU 81a. Is wound up, the efficiency of the winding process is increased, and as a result, replacement of the yarn spool is facilitated. In addition, since the feeding means used to supply the yarn during sewing is used for winding the yarn and the conventional configuration is used, a yarn winding mechanism can be realized relatively easily and at low cost. it can.
Further, the CPU 81a obtains the yarn length to be taken out each time the feeding means is driven as a reference winding amount when the yarn winding unit 30 takes up the yarn, and uses that value to take up the yarn. Control the amount quantitatively and reliably.

Since the bobbin winding unit 30 is configured to be detachable from the sewing machine main body 1a, it can be attached to the sewing machine 1 as necessary, and is highly convenient.
Furthermore, the thread winding unit 30 includes two thread spools 31 and 32, and can switch which thread of the spool is wound by the switching arm holding member 60.
Therefore, while sewing with the thread of one thread spool, if the thread spool is attached to the other thread and the thread of the former thread spool is automatically wound by the thread winding device after sewing, the latter thread The thread from the piece can be used immediately for sewing, and is particularly useful when the thread needs to be changed many times, such as in embroidery sewing.

  In addition, the winding motor 82 and the switching motor 83 are built in the sewing machine main body 1a, and when the bobbin winding unit 30 is attached to the sewing machine main body 1a, the bobbin winding unit 30 is connected to the bobbin winding unit 30 side member. Since a drive source for winding or switching is not provided in, a simple structure is sufficient.

Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate. For example, although the home embroidery sewing machine has been described as an example in the above embodiment, the present invention is not limited to home use, and may be an industrial use or may not be an embroidery sewing machine. In short, the present invention can be applied to all sewing machines that sew using a plurality of types of threads for one sewing product. The “plurality of types” is not limited to the color of the thread, and may be a color having a different property.
Further, the spool unit of the bobbin winding unit may not be two, but may be three or more. In addition, the switching mechanism for switching the thread spool for winding the thread can be freely changed, not by the motor and unit switching arm of the sewing machine body.

It is a figure which shows typically the outline | summary of the sewing machine as an example of this invention. (A) is a perspective view which shows the bobbin unit attached to the sewing machine main body, (b) is a perspective view which shows the attachment surface to the sewing machine main body of the bobbin winding unit, and the structure of the sewing machine main body side. It is a top view which shows the detail of an upper thread state detection sensor. It is a top view which shows the 1st winding part and 2nd winding part of a thread winding unit, and has shown it with a partial cross section. It is a side view which shows a 2nd winding part. It is a longitudinal cross-sectional view which shows a winding transmission body and a winding worm. It is a figure which shows the bending part of a bale. It is the perspective view which looked at the bobbin winding unit attached to the sewing machine main body from the front. It is a block diagram which shows the control circuit of a sewing machine. It is a figure which shows the example of the screen displayed on an operation panel. It is a flowchart which shows a thread winding process. 12 is a flowchart showing a continuation of FIG.

Explanation of symbols

1 sewing machine 1a sewing machine body 7 sewing needle 11 feeding roller (feeding means)
12 Feeding motor (feeding means)
20 Upper thread state detection sensor (thread detection means)
30 Yarn winding unit (yarn winding device)
31, 32 Thread stand (thread attachment part)
50 First winding part 51 Second winding part 60 Switching arm holding member (switching means)
80 control circuit 81a CPU (winding control means)
82 Winding motor (winding drive source)
83 Switching motor (switching drive source)
90 Operation panel

Claims (4)

It has a thread attachment part for attaching a thread spool,
In a thread winding device for a sewing machine that automatically winds the thread of the thread spool of the thread mounting portion,
A yarn winding device which can be detachably attached to a sewing machine. There are multiple thread attachments,
2. The yarn winding device according to claim 1, further comprising switching means capable of switching which yarn spool of the yarn attachment portion is wound. In a sewing machine provided with the yarn winding device according to claim 1 or 2,
A sewing machine characterized in that a winding drive source for winding the yarn in the yarn winding device is provided in the sewing machine body. In a sewing machine provided with the yarn winding device according to claim 2,
A sewing machine characterized in that a switching drive source of switching means in the yarn winding device is provided in the sewing machine body.

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