JP4660017B2 - Sewing machine with root winding button - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a sewing machine with a root winding button.
[0002]
[Prior art]
Conventionally, there is known a root-wound button sewing machine that automatically sews a button (hereinafter referred to as the upper button) on the fabric and winds a thread around a sewing thread (hereinafter referred to as a root thread) between the upper button and the fabric. Yes. In a conventional neck-wound button sewing machine, an XY feeder is attached to the bed, etc., and the cloth and the upper button are integrally conveyed by the XY feeder, and the needle bar is moved up and down and the looper in the bed cooperates. The upper button was sewn on the cloth. As another example, for example, the needle bar is driven to swing in the X direction, and the cloth and the upper button are moved in the Y direction, so that the cloth and the upper button are conveyed relative to the needle bar in the XY direction. Some were configured as follows.
[0003]
[Problems to be solved by the invention]
However, when the upper button and the fabric are integrally conveyed as described above, various restrictions occur, and the sewing machine cannot sufficiently cope with various sewing situations. For example, there existed a problem shown by the following (1)-(3).
(1) In a coat or the like, a reinforcing force button is often sewn on the back side of the fabric together with the upper button. The force button is formed smaller than the upper button, and therefore generally the size of the button hole of each of the upper button and the force button and the pitch between the holes are different. However, in a conventional sewing machine that conveys the upper and lower buttons and the cloth together, it is impossible to simultaneously sew the upper button and the force button having different pitches through the cloth. Therefore, a method of making a force button having the same pitch as that of the upper button and using it was used. However, in actuality, it was sewn by hand sewing, and workability was poor.
[0004]
In order to solve the above problems, Japanese Patent Application Laid-Open No. 8-117465 describes a sewing machine provided with two XY tables in order to convey the upper button and the force button independently. However, if two XY tables are provided in this way, vibration and noise when both are driven increase, and the weight of the entire sewing machine increases, which is not practical. Furthermore, since the XY table operates only when the sewing needle is removed, that is, intermittently, there is a limit to speeding up.
[0005]
(2) When the upper button is attached to the cloth, it is preferable that the needle drop position on the cloth side is approximately one place because of good appearance. That is, in the case of hand-sewing, as shown in FIG. 19 (a), if the needle is dropped at almost one place on the fabric S, and the root is wound in this state, the yarn continuous from the fabric as shown in FIG. Is linear and looks good.
However, since the relative positional relationship between the upper button and the fabric is always the same when sewing with a conventional sewing machine, the pitch of the hole of the upper button is the same as the needle drop position of the fabric. That is, as shown in FIG. 19 (c), the thread connected to the button B and the fabric S is in a parallel state corresponding to the pitch width W of the button hole. As shown in Fig. 2, the sewing thread spreads at the top and bottom of the root winding part, and the appearance was bad.
[0006]
Furthermore, there are cases where it is desired to slightly shift the needle entry position for the fabric depending on the situation. For example, at the start or end of buttoned sewing, “stop stitching” is performed in which the sewing needle is dropped multiple times in the same hole, but when the needle is dropped several times in the exact same position in the same hole, and pain in the fabric is prevented. For some reason, it may drop to a slightly different position in the same hole. In the former case, there is no problem even with a conventional sewing machine, but in the latter case, inconvenience occurs. For example, if the diameter of the sewing needle is 1 mm with respect to the diameter of the button hole of 2 mm, the sewing needle can be shifted by 0.5 mm in calculation and only about 0.3 mm in practice. Therefore, with conventional sewing machines, it is difficult to perform backtack sewing while shifting the position of the fabric within one button hole.
[0007]
(3) Normally, when manually attaching the upper button to the root button, it is sewn so that the upper thread and the root thread connected to the fabric do not come out on the back side of the fabric. Pass through. The thread that passes through the back side is called “force thread”, and the upper button is sewn to the fabric with sufficient strength. Then, the root winding is performed.
On the other hand, in the conventional sewing with a root winding button by a sewing machine, first, as shown in FIG. 20 (a), the needle B is dropped into the hole h1 in such a state that the button B is half above the folded fabric S. Sometimes the needle is dropped into the fabric, and when the needle is dropped into the hole h2, sewing is performed so that the needle does not fall into the fabric. The former is called “rake stitching” and the latter is called “empty stitching”. Then, the root thread T is formed between the button B and the fabric S by repeating the rake sewing and the empty sewing, and the thread is once cut.
[0008]
Next, as shown in FIG. 20B, the direction of the button B is changed by 90 degrees, and the root yarn is wound around the root yarn T in this state. At this time, one stitch of the root wound yarn is passed through the back side of the fabric S as a force yarn t. Therefore, the force thread t here is not the root thread T that directly connects the button B and the fabric S, but is merely wound around the root thread, unlike the original hand thread at the time of hand-sewing, so the strength is weak. . If the fabric S can be moved at the time of sewing shown in FIG. 20 (a), the root thread can be used as a force thread. However, in the conventional sewing machine, the positional relationship between the cloth and the button is fixed, which is impossible. there were.
In Japanese Patent Publication No. 2-45913, it is described that when a root thread is sewn, a cloth is moved by a cylinder to form a force thread. However, it can move only a certain distance and sewing conditions such as the size of a button. If it changed, it had to be adjusted manually and was inconvenient.
[0009]
In addition to (1) to (3), the conventional root winding button sewing machine has the following problems. When sewing with a button in line production at a sewing factory, several types of buttoned sewing are performed with one piece of clothing. For example, even with a single suit, “scooping rake sewing” shown in FIG. 20, “scraping sewing” only for rake sewing, upper button, fabric, and force button (lower button) are arranged vertically and sewed. "Sewing with buttons" is mixed. Until now, dedicated models were arranged for each sewing. Therefore, when sewing one piece of clothing, the work of removing the cloth for each type of button attachment and setting it to a dedicated model is repeated, which increases the number of manual handling steps by the operator and the work efficiency is poor. It was. In addition, a large amount of capital investment was required to prepare dedicated machines for each type of button attachment.
[0010]
An object of the present invention is to provide a root winding button sewing machine that can convey buttons and fabrics separately, can cope with various sewing conditions, and can improve work efficiency.
[0011]
[Means for Solving the Problems]
In order to solve the above problems, the invention described in claim 1 is, for example, as shown in FIGS.
Needle up / down drive means (needle up / down movement mechanism 10) for driving a needle bar (9) having a sewing needle (5) at the lower end thereof up and down by a main shaft (7) installed substantially horizontally;
Needle swing drive means (needle swing mechanism 11) for swinging the needle bar in a plane parallel or perpendicular to the longitudinal direction of the main shaft;
Cloth feed driving means (lower Y feed mechanism 50) for driving a cloth feed plate (lower plate 56) for placing the lower button and the sewing product on the upper surface in a direction orthogonal to the needle swing direction of the needle swing drive means;
First button feed driving means (upper Y feed mechanism 30) for driving an upper button gripping part (chuck part 90) for gripping the upper button substantially horizontally in a direction parallel to the cloth feed direction of the cloth feed drive means;
Second button feed driving means (button differential mechanism 70) for driving the upper button gripper in a direction orthogonal to the drive direction of the first button feed drive means and parallel to the needle swing direction;
A root winding button sewing machine (sewing machine 1) comprising control means (CPU 102) for controlling each of the driving means.
[0012]
According to the first aspect of the present invention, the sewing needle swings in a plane parallel or perpendicular to the longitudinal direction of the main shaft by the needle swing driving means. Further, the upper button can be moved in the same direction as the cloth feeding direction by the first button feed driving means and in the same direction as the needle swinging direction by the second button feed driving means orthogonal thereto. Further, the lower button and the fabric can be moved in a direction orthogonal to the needle swinging direction by the cloth feed driving means. If the swinging motion of the sewing needle is used, the lower button and the fabric can be moved in the direction orthogonal to the cloth feed driving means relative to the upper button. That is, the upper button and the fabric (lower button) can be driven in two directions orthogonal to each other in the horizontal plane.
Therefore, by combining these driving means, the relative positional relationship between the upper button and the fabric (lower button) can be freely changed, and various buttons can be attached which was impossible in the past.
[0013]
As described above, the upper button and the fabric (lower button) can be freely moved in two directions perpendicular to each other, but the lower button uses a needle swing mechanism, so that Compared with the case where two XY tables are provided and driven, the overall weight can be reduced. In addition, since the needle bar swings and the XY table moves only when the needle is positioned above the needle plate, it is an intermittent motion anyway. Dynamic motion is faster than driving the table, enabling high-speed operation and high work efficiency.
[0014]
The invention according to claim 2 is, for example, as shown in FIG.
Needle up / down driving means for driving a needle bar having a sewing needle at the lower end portion up and down by a main shaft installed substantially horizontally;
Needle swing drive means for swinging the needle bar in a plane parallel or perpendicular to the longitudinal direction of the main shaft;
A cloth feed driving means for driving a cloth feed plate for placing the lower button and the sewing product on the upper surface in a direction orthogonal to the needle swinging direction of the needle swing driving means;
First button feed driving means for driving the upper button gripping part for gripping the upper button substantially horizontally in a direction parallel to the cloth feeding direction of the cloth feed driving means, and the driving direction of the first button feed driving means for the upper button gripping part Any one of the second button feed driving means for driving in a direction perpendicular to the direction and parallel to the needle swing direction;
A root winding button sewing machine comprising: a control unit that controls each of the driving units.
[0015]
According to the second aspect of the present invention, the sewing needle swings in a plane parallel or perpendicular to the longitudinal direction of the main shaft by the needle swing driving means. The upper button can be moved in the same direction as the cloth feeding direction or the needle swinging direction by the first button feed driving means or the second button feed driving means. Further, the lower button and the fabric can be moved in a direction orthogonal to the needle swinging direction by the cloth feed driving means.
In other words, the upper button, the fabric (lower button), and the sewing needle can be driven in one direction. By combining these driving means, the relative positional relationship between the upper button and the fabric (lower button). Can be freely changed to some extent, and various buttons can be attached which was impossible in the past.
[0016]
A third aspect of the present invention is the root winding button sewing machine according to the first or second aspect,
The cloth feeder is
A cloth holding section (cloth holding section 60, position A) that holds the sewing product in a folded state and enables rake sewing;
A lower button holding portion (position B) that holds the lower button below the sewing product and enables sewing with the lower button;
An upper button sticking portion (position C) that enables sticking sewing for sticking the upper button to the upper surface of the sewing product,
The cloth feed driving means is characterized in that the cloth feed plate can be driven so that each of the cloth holding part, the lower button holding part, and the upper button sticking part is located substantially below the sewing needle.
[0017]
According to the third aspect of the present invention, the cloth feed plate is provided with the cloth holding portion, the lower button holding portion, and the upper button sticking portion as positions corresponding to various button sewing operations, and the cloth feed driving means holds the cloth. The cloth feed plate is driven so that each of the upper part, the lower button holding part, and the upper button sticking part is located substantially below the sewing needle. Therefore, when three types of buttons are attached to one piece of clothing, such as rake stitching, bottom button stitching, and sticky stitching, one sewing machine can be used. There is no need to move the sewing product from the sewing machine to the sewing machine or change the attachment, improving work efficiency. In addition, the cost can be reduced compared to purchasing a sewing machine for each type of button attachment.
[0018]
Further, as described above, conventionally, a force thread cannot be formed in rake stitching, and has been used as a substitute for a force thread by passing it through the fabric back side during root winding. However, in the sewing machine according to the third aspect, during the process of forming the root thread by scoop sewing in the cloth holding portion, the sewing thread is passed through the back side of the cloth during scoop sewing by moving the cloth relative to the upper button. Since a force yarn can be formed, the upper button can have sufficient tensile strength.
[0019]
According to the third aspect of the present invention, it is possible to perform programmed sewing as in the fourth aspect of the invention.
That is, the invention according to claim 4 is the invention according to claim 3,
Storage means (memory 102a) for storing a cycle stitching program for continuously sewing two or more different types of button stitching including rake stitching, bottom button stitching, and solid stitching;
The control means controls the driving means so as to perform cycle sewing in accordance with the cycle sewing program.
[0020]
According to the fourth aspect of the invention, under the control of the control means, each driving means operates in accordance with the cycle sewing program stored in the storage means, and specifically, the cloth feed plate is driven by the cloth feed drive means. Then, it is possible to automatically move the cloth holding portion, the lower button holding portion, and the upper button sticking portion to a predetermined position below the sewing needle in an appropriate order. Accordingly, it is possible to further reduce the time interval when continuously sewing different types of button-attached sewing, thereby improving work efficiency.
[0021]
If it is a sewing machine with a root winding button according to claim 1 or 2, the relative positional relationship between the upper button and the lower button can be freely set, and the type of the upper and lower buttons and the hole pitch as in claim 5. You can sew regardless of the.
That is, the invention according to claim 5 is the root winding button sewing machine according to claim 1 or 2,
It is possible to sew a lower button with a combination of an upper button and a lower button in which at least one of the number of holes, the pitch of the holes, and the arrangement of the holes is different.
[0022]
In the conventional sewing machine, when the upper and lower buttons are sewn with the sewing machine, there is a restriction that the upper and lower buttons having the same hole pitch must be used. However, in the sewing machine of the present invention, as in the invention described in claim 5, the upper and lower buttons can be selected without restriction, and various combinations can be selected, and the width of button sewing is increased.
Here, since “at least one of the number of holes, the pitch of the holes, and the arrangement of the holes is different”, all may be different.
[0023]
Furthermore, since the upper button and the fabric can be moved relatively freely with the sewing machine according to claim 1, the sewing machine according to claim 6 can be used for both rake sewing and solid sewing. You can control the needle entry point.
That is, the invention described in claim 6 is the root winding button sewing machine according to claim 1,
The stitching position of the sewing needle that passes through the button hole of the upper button to the sewing product is a stitch that concentrates on one point, a stitch that concentrates on two predetermined points, and a stitch that has three or more predetermined points Each can be formed.
More specifically, when the needle drop points are concentrated on one point, when the button and the fabric are viewed from the side, the sewing thread connected to both becomes “V-shaped”. If this is followed by root winding sewing, stitches with good texture can be formed.
In addition, when the sewing thread is thick and the needle drop occurs at the same location of the fabric, the needle drop may be made at three or more predetermined points. Alternatively, when it is desired to stabilize the upper button so that the upper button is supported by the root thread, the needle may be dropped at two predetermined points so as to have an interval larger than the hole pitch of the button holes. Of course, the needle drop may be made at two predetermined points with the same interval as the hole pitch of the button holes, or the needle drop may be made at two predetermined points narrower than the hole pitch.
[0024]
Furthermore, since the cloth can be moved with respect to the upper button in the sewing machine according to claim 1 or 2, the needle drop point at the time of back stitching can be controlled like the sewing machine according to claim 7.
A seventh aspect of the present invention is the root winding button-attached sewing machine according to the first or second aspect,
It is characterized in that the needle drop can be made at a plurality of positions on the sewing product without being limited by the size of the button hole in the back-stitching in which the sewing needle is passed through the same button hole a plurality of times.
[0025]
In a conventional sewing machine, when a needle is dropped several times into one button hole, the needle has to be dropped at almost the same location on the fabric. However, according to the seventh aspect of the invention, the needle drop can be caused to pass through one button hole by moving the sewing product regardless of the position of the upper button. Accordingly, for example, it is suitable when the sewing thread is considerably thick with respect to the texture of the fabric and it is not preferable to drop the needle at the same position.
[0026]
The invention according to claim 8 is the root winding button sewing machine according to any one of claims 1 to 7,
Rotating means (button rotating means 46) for rotating the upper button gripping part by 90 degrees so that the upper button is vertically supported is provided.
According to the eighth aspect of the present invention, the upper button gripping portion can be rotated 90 degrees by the rotating means, so that the upper button is fixed in the state where the upper button is raised at the time of root winding sewing or sewing of the shank button. can do.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 shows a schematic configuration of an appearance of a sewing machine 1 as an example of a root winding button sewing machine according to the present invention together with a block diagram of a control circuit. The sewing machine 1 includes a bed portion 2, a vertical trunk portion 3 standing from the bed portion 2, and an arm portion 4 extending from the vertical trunk portion 3 so as to face the bed portion 2. In the following description, the front-rear direction and the up-down direction of the sewing machine 1 are as shown in FIG. The direction perpendicular to the paper surface of FIG. 1 is the left-right direction (X direction, FIG. 2).
[0028]
The sewing machine 1 is fixed to the tip of a needle bar 9 provided at the tip of the arm portion 4, and a sewing needle 5 through which a thread is passed, and a bed portion 2 provided so as to face the sewing needle 5 (not shown). A button is automatically sewn to a cloth (sewn product) in cooperation with a looper. Since the formation of the seam such as the operation of the looper is a well-known technique, a detailed description thereof will be omitted.
The sewing machine 1 can be sewn with various buttons by independently transporting an upper button, a fabric and the like independently. Hereinafter, various mechanisms for transporting buttons and the like will be described in detail. In the following description, a so-called front button is described as an up button, and a button attached to the back side of the fabric with respect to the front button as a force button is described as a lower button.
[0029]
2 to 4 are views showing the needle up-and-down moving mechanism 10 and the bowl swinging mechanism 11 provided in the sewing machine 1.
The needle up / down movement mechanism (needle up / down drive means) 10 drives the sewing needle 5 up and down, and uses a spindle motor 14 fixed inside the sewing machine 1 as a drive source. The output shaft of the main shaft motor 14 is connected to the main shaft 7 provided in the horizontal direction while being rotatably supported by a bearing 7a. Further, a counterweight 18 is attached to the tip of the main shaft 7. A balance link 16 and a balance 25 are provided adjacent to the counterweight 18. One end of the balance link 16 and the base of the balance 25 are pivotally supported with respect to the counterweight 18, respectively, and move up and down along a predetermined locus as the counterweight 18 rotates.
The other end portion of the balance link 16 is rotatably attached to one end portion of a needle bar crank 19 fixed to the eccentric position of the counterweight 18, and the other end portion of the needle bar crank 19 has a needle bar crank rod 26. The upper end is pivotally attached. A shaft hole 26 a is formed at the lower end of the needle bar crank rod 26. A guide member 29 having a guide groove 29a formed in the vertical direction is provided behind the needle bar crank rod 26, and a square piece 27 is slidably fitted in the guide groove 29a. A shaft hole 27a is formed in the square piece 27 in the horizontal direction.
[0030]
On the other hand, an upper and lower rod 28 is provided in front of the needle bar crank rod 26. The upper and lower rods 28 are formed with two shaft holes arranged in the vertical direction, and the shaft fixed to the needle bar holder 8 that supports the needle bar 9 is rotatably supported in the upper shaft hole (not shown). Has been passed. A shaft (not shown) is passed through the shaft hole 28a below the upper and lower rods 28, the shaft hole 26a of the needle bar crank rod 26, and the shaft hole 27a of the square piece 27. The vertical movement of 26 is transmitted to the square piece 27 and the vertical rod 28. In FIG. 4, for convenience of description, the shaft holes 27a, 26a, and 28a are shown in a vertically displaced state so that the shaft holes 27a, 26a, and 28a can be seen, but actually they are aligned in a straight line in the horizontal direction. .
In the needle up-and-down moving mechanism 10 having the above configuration, when the main shaft 7 is rotated by the rotation of the main shaft motor 14, the counterweight 18 is rotated, and one end portion of the needle bar crank 19 is rotated about the main shaft 7, whereby the needle bar is rotated. The crank rod 26 moves up and down. This vertical movement is transmitted to the needle bar 9 via the vertical rod 28 and the needle bar holder 8 so that the sewing needle 5 moves up and down.
[0031]
The needle swing mechanism (needle swing drive means) 11 reciprocally swings the sewing needle 5 left and right, and uses a needle swing motor 20 that is a pulse motor as a drive source. The needle swing motor 20 is fixed to the machine frame of the sewing machine 1 and rotates in synchronization with the spindle motor 14. A first link 24 is connected to the output shaft, a second link 23 is connected to the first link 24, and a third link 22 is connected to the second link 23 in order. The rear end portion of the needle bar swinging rod 12 that is long in the front-rear direction is connected to the third link 22 so as to be rotatable. A swing arm 13 having a substantially L-shape is fixed to the front end of the needle bar swing bar 12, and a swing angle piece 15 is attached to the tip of the swing arm 13.
On the other hand, the needle bar 9 is supported so as to be slidable in the vertical direction with respect to the needle bar rocking base 6 at the middle part and the upper part thereof. The needle bar swing base 6 is configured to be swingable in the X direction around a fulcrum pin 17. A groove 6a is formed in the vertical direction at the lower end of the needle bar swinging base 6, and a swing angle piece 15 is fitted in the groove 6a so as to be slidable in the vertical direction.
[0032]
In the needle swinging mechanism 11 having the above configuration, when the needle swinging motor 20 is actuated, the rotation is transmitted to the needle bar swinging rod 12 via the first link 24, the second link 23, and the third link 22, and the reciprocating swinging is performed. Move. This swing is transmitted to the needle bar swing base 6 via the swing angle piece 15, and the needle bar swing base 6 swings in the X direction together with the needle bar 9 around the fulcrum pin 17, thereby sewing. The needle 5 is swung.
By the way, the upper and lower rods 28 are rotatable with respect to the shafts passed through the upper and lower shaft holes, and can be rotated around the shaft hole 28a in accordance with the swing of the needle bar 9 in the vertical plane. Therefore, the needle bar 9 can be swung in the X direction by the needle bar rocking base 6 together with the needle bar hugging 8 while being driven up and down by the needle bar hugging 8.
The needle swing motor 20 operates in synchronism with the main shaft motor 14 as described above, but specifically, only when the sewing needle 5 is positioned above the needle plate (not shown) on the upper surface of the bed 2. The needle bar 9 is controlled to swing.
[0033]
By the way, a lateral component of inertia force generated by the crank motion of the needle bar crank 19 is generated in the needle bar crank rod 26 of the needle up-and-down moving mechanism 10. However, the lateral force is transmitted to the square piece 27 and absorbed in the guide groove 29a, and as a result, the laterally swaying force is not transmitted to the needle bar 9 side. With this configuration, the needle bar swinging rod 12 is not subjected to a force against the load generated on the needle vertical movement mechanism 10 side, and the needle bar 9, the needle bar swing base 6, and the swing arm 13. Only the load due to the inertia of the swinging is applied, and the load applied to the needle bar swinging rod 12 is not so large, and high speed operation is possible.
[0034]
5 and 6 show an upper Y feed mechanism 30 that conveys the upper button B gripped by the chuck portion 90 in the Y direction and a button differential mechanism 70 that conveys the upper button B in the X direction.
The top Y feed mechanism (first button feed drive means) 30 uses a top Y feed motor 32 fixed inside the central portion of the arm portion 4 as a drive source. The upper Y feed motor 32 is configured to be rotatable forward and backward, and a pinion 32a is fixed to the output shaft thereof.
An upper Y feed base 36 is provided at the central portion of the arm portion 4 so as to protrude into a so-called pocket portion. On the upper surface 36 b of the upper Y feed base 36, base guide portions 36 a and 36 a that engage with the arm guide portions 31 and 31 fixed to the arm portion 4 are provided. The arm guide portions 31 and 31 and the base guide portions 36a and 36a are engaged with each other so as to be linearly slidable in the Y direction.
At the edge of the upper Y feed base 36, a rack support base 36c for supporting the rack 33 is provided on the upper surface, and the pinion 32a is engaged with the rack 33. Therefore, when the upper Y feed motor 32 rotates in one direction and the pinion 32a rotates, the upper Y feed base 36 moves in either the front or rear direction via the rack 33.
[0035]
A position sensor 42 made of a photo interrupter is provided in the arm portion 4 and in the vicinity of the rack support base 36c. On the other hand, a sensor plate 33 a is fixed to the side surface of the rack 33. When the rack 33 moves forward by a predetermined distance, the sensor plate 33a passes between the position sensors 42, which are photo interrupters, thereby detecting that the rack 33 has reached the limit position in the front, and further moving forward. It abuts against a stopper (not shown) and cannot move further forward.
[0036]
The upper Y feed base 36 is provided with a button up-and-down moving mechanism 40 that moves up and down a chuck unit 71 described later. The button vertical movement mechanism 40 is mounted inside the upper Y feed base 36, and is a vertical drive motor 35 capable of rotating both forward and reverse, an upper and lower pinion 35a fixed to the output shaft of the vertical drive motor 35, and an upper Y feed base. The upper and lower racks 41 are attached to the side surfaces of 36 along the vertical direction. The upper and lower racks 41 are fixed to the chuck support arm 34 that supports the chuck unit 71 via a rack support plate 41a.
Therefore, when the vertical drive motor 35 rotates in one direction and the vertical pinion 35a rotates, the vertical rack 41 moves up and down so that the chuck support arm 34 moves up and down via the rack support plate 41a. It has become. An upper and lower guide rod 43 that guides the vertical movement of the rack support plate 41a is provided in the vicinity of the upper and lower pinions 35a.
[0037]
A button rotating mechanism (rotating means) 46 for rotating the chuck unit 71 by 90 degrees is provided in the vicinity of the button up-and-down moving mechanism 40, and a rotating cylinder 37 provided on the upper side surface of the chuck support arm 34 is used as a driving source. The rotary cylinder 37 is a double-acting air cylinder having two air ports 37a and 37a, and can drive the output rod 37b back and forth.
One vertex of a triangular link 38 formed in a substantially triangular shape is rotatably connected to the tip of the output rod 37b. One end of an elongated main link 39 provided along the chuck support arm 34 is connected to the second vertex of the triangular link 38. The third vertex of the triangular link 38 is connected to the chuck support arm 34. The other end of the main link 39 is connected to a rotating body 45 provided between the lower end of the chuck support arm 34 as shown in FIG. A unit shaft 81 a extending from a unit support arm 81 that supports the entire chuck unit 71 is fixed to the rotating body 45. A shaft hole (not shown) is formed in the lower end portion of the chuck support arm 34, and the unit shaft 81a passes through the shaft hole in a rotatable state.
[0038]
In the button rotation mechanism 46, the triangular link 38, the main link 39, the rotating body 45, and the chuck support arm 34 constitute a four-bar link having the chuck support arm 34 as a fixed link. As the output rod 37b moves back and forth, the rotator 45 rotates 90 degrees clockwise or counterclockwise, whereby the chuck unit 71 rotates 90 degrees via the unit shaft 81a. Specifically, the chuck unit 71 holds the upper button B in the horizontal direction with the output rod 37b pushed out (the state shown in FIGS. 5 and 6). 6 Rotate clockwise and hold so that the upper button B stands. The root winding process is performed in this state.
[0039]
Next, the chuck unit 71 will be described with reference to FIGS. FIG. 9 shows the motor unit 77 removed. The chuck unit 71 includes a chuck portion 90 that chucks the upper button B, and a button differential mechanism 70 that drives the chuck portion 90 in the X direction.
The chuck portion 90 includes chuck pieces 91a and 91b provided so as to face the left and right, and holds the upper button B between them. The chuck piece 91a is fixed to a chuck mounting portion 92a provided at a lower portion of the chuck movable member 92 formed in an L shape. On the other hand, the chuck piece 91b is fixed to a chuck mounting portion 93a provided at a lower portion of the chuck movable member 93 formed in an L shape shorter than the chuck movable member 92.
[0040]
7 and 8, the chuck movable members 92 and 93 are respectively provided with guide grooves 74a and 74b formed on the lower surface of the base 74 provided between the chuck piece 91b and the support arm 81. It is slidably fitted to. A manual lever 82 (indicated by a broken line in FIG. 8) for manual operation is attached to the lower surface of the base 74 by a screw 83 so as to be rotatable around the screw 83. Pins 92 b and 93 b projecting downward are fixed to the lower surfaces of the chuck movable members 92 and 93, and these penetrate through holes (not shown) having a predetermined shape formed in the manual lever 82.
Therefore, when the manual lever 82 rotates about the screw 83 in the clockwise direction in FIG. 8, the chuck movable member 92 is pushed to the left via the pin 92b, and the chuck movable member 93 is moved to the right via the pin 93b. By pulling, the space between the chuck pieces 91a and 91b is widened, and the upper button B can be removed. When the manual lever 82 rotates about the screw 83 in the counterclockwise direction in FIG. 8, the chuck movable member 92 is pulled to the right via the pin 92b, and the chuck movable member 93 is moved to the left via the pin 93b. As a result, the distance between the chuck pieces 91a and 91b approaches and the upper button B can be gripped.
A stopper plate 79 of the manual lever 82 is fixed to the front edge portion of the base 74 with screws 74c. The elongated hole 79a is an elongated hole for adjusting the distance between the chuck pieces 91a and 91b.
[0041]
The button differential mechanism (second button feed drive means) 70 drives the chuck portion 90 to the left and right, and mainly includes a differential base 80 fixed to the unit support arm 81, a differential motor 72, and a stopper. The member 78 is comprised. As shown in FIG. 9, the differential base 80 has a long hole 80a which is long in the left and right in the center, and two of the long holes 80a are formed into fine holes 80b and 80b. . The pores 80b, 80b have a predetermined length with a predetermined width, and step screws 75, 75 fixed to the base 74 are fitted therein. As the step screws 75 and 75 move along the pores 80 b and 80 b, the base 74 can reciprocate in the left-right direction with respect to the differential base 80.
[0042]
On the differential base 80, a motor unit 77 having a substantially U-shaped cross section is screwed, and a differential which is a linear motor between left and right wall portions 77a and 77b constituting the motor unit 77. A motor 72 is fixedly supported. The output shaft 72a of the differential motor 72 passes through the wall portions 77a and 77b and protrudes to the left and right sides. The output shaft 72a goes straight in either the left or right direction when the differential motor 72 operates.
On the other hand, a stopper member 78 is erected on the upper surface of the left portion of the base 74 by screws. Between the stopper member 78 and the wall portion 77a, springs 73, 73 are urged to urge both the members in the direction in which they approach each other. By means of the springs 73, 73, the stopper member 78 always comes into contact with the output shaft 72a.
[0043]
In the button differential mechanism 70 configured as described above, when the differential motor 72 operates in one direction, the output shaft 72a goes straight to the left. By the straight advance of the output shaft 72 a, the stopper member 78 is pushed to the left, and the base 74 that fixes and supports the stopper member 78 slides to the left with respect to the differential base 80. Since the chuck movable members 92 and 93 are engaged with the base 74, the chuck portion 90 moves to the left together with the base 74. On the contrary, when the output shaft 72a moves to the right by the operation of the differential motor 72 in the reverse direction, the stopper member 78 also moves to the right by the urging force of the springs 73, 73. 90 also moves to the right.
[0044]
Next, based on FIGS. 10 to 12, the lower Y feeding mechanism 50 provided in the bed portion 2 and transporting the fabric and the lower button in the Y direction will be described.
The lower Y feed mechanism (cloth feed drive means) 50 uses a lower Y feed motor 51 as a drive source, and a sprocket wheel 52 is fixed to the output shaft of the motor 51. Further, a timing belt 53 stretched in the front-rear direction is hung on the sprocket wheel 52 so as to be engaged therewith. Further, the timing belt 53 is also hung on a rotatable driven roller 58, and when the lower Y feed motor 51 rotates, the timing belt 53 rotates through a sprocket wheel 52.
A lower shaft 69 for driving a looper (not shown) is provided in the vicinity of the timing belt 53. The rotation of the spindle motor 14 is transmitted to the lower shaft 69 via timing belts 68a, 68b, etc., so that the looper operates in synchronization with the spindle 7.
[0045]
As shown in FIG. 12, Y feed bases 54 and 54 are screwed to the timing belt 53 via fixing plates 63a and 63a. Guide shafts 55 a and 55 b are fixed to a frame (not shown) in the bed portion 2 so as to be parallel to the timing belt 53. The guide shaft 55a penetrates the bases 54a and 54a of the Y feed bases 54 and 54, and the guide shaft 55b penetrates the tip parts 54b and 54b of the Y feed bases 54 and 54, and the Y feed bases by these guide shafts 55a and 55b. 54, 54 are supported.
Screw holes 54c and 54c are formed on the upper surfaces of the tip portions 54b and 54b. These screw holes 54c and 54c are aligned with screw holes (not shown) formed in the lower plate 56, and are fastened with set screws 56c and 56c, thereby lowering the Y feed base 54 as shown in FIG. The plate 56 is fixed. Therefore, as the lower Y feed motor 51 is operated and the Y feed base 54 is moved by the timing belt 53, the lower plate 56 is also moved in the Y direction.
[0046]
The lower plate (cloth feed plate) 56 is for placing fabric and lower buttons on its upper surface, and the lower plate 56 of the present invention has three button attachment positions A, B, C.
The position A is a place where rake sewing, root winding sewing, or both are performed. The lower plate 56 is formed with a substantially L-shaped large opening 56a. On the other hand, the foremost part of the lower plate 56 is provided with a cloth holding part (cloth holding part) 60 that includes two spring holding parts 60a and 60a arranged side by side and holds the cloth together with the tongue 57. Each spring clamping part 60a is comprised from the thin leaf | plate spring which opposes up and down. A needle hole 60b is provided at the rear edge of the cloth holding portion 60 so as to face the opening 56a.
[0047]
Here, the tongue 57 for setting the fabric to the cloth clamping unit 60 will be described. A cylinder base 65 that supports a tongue cylinder 66 that drives a tongue 57 is fixed to the lower part of the Y feed bases 54 and 54. The output rod 66 a of the tongue cylinder 66 is connected to the tongue link 67. On the other hand, the tongue 57 is screwed to the tip of a tongue support portion 59 formed in an arc shape. A tongue shaft 59a is inserted into the base end portion of the tongue support portion 59 and the tongue link 67, and the tongue link 67 and the tongue support portion 59 can be rotated together with the tongue shaft 59a.
[0048]
The operator sets the fabric so as to wrap the front end portion of the tongue 57, and manually pushes and moves the hand pressing portion 57a of the tongue 57 so as to approach the lower plate 56 in this state. A tongue sensor 64 (FIG. 1) is provided in the vicinity of the lower plate 56, and outputs a tongue detection signal to the CPU 102 when the tongue 57 approaches. In response to this, the tongue cylinder 66 is turned on under the control of the CPU 102, the output rod 66a is retracted, and thereby the tongue 57 advances to the cloth holding portion 60. Finally, the cloth is folded and remains. It is sandwiched between the left and right spring clamping portions 60a, 60a. At this time, the needle hole 57b formed at the tip of the tongue 57 is substantially coincident with the needle hole 60b when viewed from above and below. With respect to the fabric set in this way, the upper button chucked by the chuck portion 90 is set above the lower plate 56 so that the needle hole 60b is located at the approximate center thereof as shown by the dotted line in FIG. Is done. By setting the fabric and the upper button in this manner, rake sewing as shown in FIG. 20A is possible.
[0049]
When root winding sewing is performed after rake stitching, the upper button is rotated 90 degrees in the clockwise direction in FIG. By rotating in this way, the upper button is erected in a state where it faces the opening 56a, and the root thread between the upper button and the cloth is directed in the front-rear direction, and root winding sewing is possible.
The tongue cylinder 66 is automatically turned off when the sewing is completed, and the tongue 57 returns to the original standby position.
[0050]
Behind the opening 56a, a needle plate 61 constituting positions B and C is fixed at its base. A concave portion 61a is formed in the front edge portion of the needle plate 61, and a needle hole 61b is formed in the central portion. In the lower plate 56, elongated holes 56b serving as needle holes are formed at locations corresponding to the recesses 61a and the needle holes 61b.
The concave portion 61a is at the position B, the lower button is set between the concave portion 61a and the lower plate 56, the fabric is placed thereon, and the upper button gripped by the chuck portion 90 is further set thereon, The bottom button can be sewn. Therefore, the position B is the lower button holding portion of the present invention.
Needle hole 61b is at position C, a cloth is placed on needle hole 61b, the upper button gripped by chuck portion 90 is set above it, and the button is attached by solid stitching without the lower button. It can be carried out. Therefore, the position C is the upper button sticking portion of the present invention.
In the case of sewing at positions B and C, the fabric is pressed by a presser foot (not shown), and the presser foot is driven by a presser foot cylinder 107 (FIG. 1).
In this way, the lower plate 56 has three types of button sewing positions, and the lower Y feed mechanism 50 drives the lower plate 56 so that each of the positions A, B, and C is positioned below the sewing needle 5. Is done. Reference positions (origins) and initial positions are set for the positions A, B, and C, respectively.
[0051]
Next, the control circuit of the sewing machine 1 will be described with reference to FIG. The sewing machine 1 is provided with an electrical box 101 including a CPU (Central Processing Unit) 102 which is a control means of the present invention, and each part is connected to the electrical box 101.
For example, an operation panel 103, a power switch 104, a start pedal 105, and a temporary stop switch 106 are connected to the electrical equipment box 101.
The operation panel 103 allows the operator to select the type of buttoning from the rake sewing without the root winding sewing, the rake root winding sewing, the bottom button sewing, the solid sewing, etc., or input the sewing conditions for the selected button sewing. Or a set sewing condition or sewing status is displayed. An external memory 103a can be connected to the operation panel 103, and sewing conditions can be set by reading sewing data from the external memory 103a.
[0052]
The CPU 102 is provided with a memory (storage means) 102a, and various programs are stored in the memory 102a. In particular, the memory 102a stores a cycle sewing program for continuously attaching different types of buttons, and when the lower plate 56 is driven by the lower Y feed mechanism 50 by calling the program, Positions A, B, and C are moved to the position.
[0053]
The power switch 104 is an ON / OFF switch for turning on the sewing machine 1. The start pedal 105 is a pedal that is operated when sewing is started, and when this is operated, sewing is started under the control of the CPU 102. The temporary stop switch 106 is a switch for temporarily stopping after starting sewing.
In addition, an interface (not shown) is provided in the electrical box 101, and a control signal from the CPU 102 is output to each drive source via this interface.
That is, the spindle motor 14, the needle swing motor 20, the upper Y feed motor 32, the vertical drive motor 35, the differential motor 72, and the lower Y feed motor 51 are connected via the interface. The electromagnetic valve 108 is connected via the interface, and the rotary cylinder 37, the tongue cylinder 66 and the presser foot cylinder 107 are connected via the electromagnetic valve 108. Further, the sewing machine 1 is provided with a thread trimming mechanism (not shown) so that the thread is cut at a predetermined timing during or after sewing, and a thread trimming motor 109 and a thread trimming cylinder 110 are used as driving sources. Is provided.
[0054]
The sewing machine 1 having the above configuration can be moved in the X direction and the Y direction with respect to the upper button by the button differential mechanism 70 and the upper Y feed mechanism 30. Further, the lower button and the fabric can be moved in the Y direction by the lower Y feeding mechanism 50. In addition, by using the needle swing mechanism 11 movable in the X direction, the lower button and the fabric can be moved in the X direction relative to the upper button. Further, the upper button can be moved up and down by the button up-and-down moving mechanism 40, and the direction can be changed by 90 degrees by the rotating cylinder 37. By combining these mechanisms, it has become possible to handle various button attachments that were difficult in the past.
Below, based on FIGS. 13-17, the operation | movement at the time of buttoning in the sewing machine 1 is given as an example, and is demonstrated.
[0055]
(1) In the case of four-hole up button and four-hole down button
Before the buttoning operation in the sewing machine 1, the button and the fabric are set. That is, the upper button B1 having four holes is supplied to the chuck portion 90 manually or by a known button feeder device, and the upper button is gripped by the chuck portion 90. When the chuck portion 90 chucks the upper button B1, it is detected by a sensor (not shown), and the upper button B1 is lowered to a predetermined origin position by the button vertical movement mechanism 40. On the other hand, the lower button C1 having four holes is set at the position B of the lower plate 56 at the predetermined origin position, and the fabric is placed on the upper portion thereof.
FIG. 13A shows an initial state in which the upper button B1 and the lower button C1 are set as described above. For convenience, fabric is not shown. At this time, the sewing needle 5 is above the point P1 in FIG. 13A, that is, the center of the upper button B1 and the lower button C1 coincides with the sewing needle 5.
[0056]
A. Vertical eye
First, “longitudinal stitch” sewing for threading in the Y direction, for example, dropping the first needle into the hole b1 of the upper button B1 and the hole c1 of the lower button C1, and then dropping the second needle into the hole b2 and the hole c2 Is described.
By operating a preparation key (not shown) provided on the operation panel 103 in the set state as shown in FIG. 13A, each mechanism operates as follows.
A. By the needle swing mechanism 11, the sewing needle 5 at point P1 moves by a distance half the distance w1 (c1-c3, c2-c4) between the centers of the holes arranged on the left and right of the lower button C1, and moves to the point P2.
I. The lower Y feed mechanism 50 causes the lower button C1 (cloth) to move by a distance half the distance w2 (c1-c2, c3-c4) between the centers of the holes arranged in the front-rear direction, and the hole c1 moves to the point P2. (Indicated by dotted lines).
C. The upper Y feed mechanism 30 moves the upper button B1 by a distance half the distance W2 (b1-b2, b3-b4) between the centers of the holes arranged in the front-rear direction. Next, the button differential mechanism 70 moves the upper button B1 by a distance m1 between the centers of the upper and lower buttons, and the hole b1 moves to the point P2 (indicated by a dotted line).
The above operations (a) to (c) are performed almost simultaneously, whereby the sewing needle 5, the hole b1, and the hole c1 gather at the point P2.
[0057]
Next, when the start pedal 105 is depressed, the spindle motor 14 starts to rotate, the first sewing needle 5 descends, passes through the hole b1, the fabric, and the hole c1, and the thread is entangled with the looper, and then the sewing needle 5 Rises. When the needle tip moves above the upper button B1, each mechanism operates as follows.
D. The lower Y feed mechanism 50 moves the lower button C1 (cloth) by the distance w2, and the hole c2 indicated by the dotted line moves to the point P2.
E. The upper Y feed mechanism 30 moves the upper button B1 by the distance W2, and the hole b2 indicated by the dotted line moves to the point P2.
The above operations (e) and (e) are performed simultaneously, whereby the sewing needle 5, the hole b2, and the hole c2 gather at the point P2. Next, the sewing needle 5 is lowered and the second stitch is sewn. When the second needle rises, each mechanism operates so that the holes b1 and c1 gather again at the point P2, and the third stitch is sewn. By repeating the above operation several times, vertical seams are formed between b1-b2 and between c1-c2. At the end of this seam, when the sewing needle 5 falls in the same hole b1 and hole c1 as the sewing start position and the thread gets entangled with the looper, the sewing needle 5 rises. Here, the spindle motor 14 temporarily stops. Further, the sewing thread is cut by the thread trimming means according to the setting.
[0058]
Next, each mechanism operates as follows to form a seam between b3-b4 (c3-c4).
F. By the needle swing mechanism 11, the sewing needle 5 at point P2 moves by w1 and moves to point P3. As a result, the sewing needle 5 is positioned on the hole c3 indicated by the dotted line.
G. By the button differential mechanism 70, the upper button B1 moves twice as long as the distance m1, and the center of the hole b3 indicated by the dotted line moves to the point P3.
As a result, the sewing needle 5, the hole b3, and the hole c3 are gathered at the point P3, and the spindle motor 14 starts to rotate here. Thereafter, the operation continues in exactly the same way as between b1 and b2 (c1 and c2), and warp stitches are formed between b3 and b4 (c3 and c4). Finally, the sewing thread is cut by the thread trimming means. The sewing is finished.
[0059]
B. Yokome
In the case of the horizontal eye, as in the case of the vertical eye, by operating the preparation key from the initial state shown in FIG. The needle 5, the hole b1, and the hole c1 are gathered (the state of the dotted line in FIG. 13A).
Next, when the start pedal 105 is operated and the first stitch falls to the point P2, the sewing needle 5 rises and the needle tip reaches above the upper button B1, each mechanism operates as follows.
H. By the needle swing mechanism 11, the sewing needle 5 at point P2 moves by the distance w1 and moves to point P3. The lower Y feed mechanism 50 and the upper Y feed mechanism 30 do not move.
I. By the button differential mechanism 70, the upper button B1 moves twice as long as the distance m1, and the hole b3 indicated by the dotted line moves to the point P3.
As a result, the sewing needle 5, hole b3, and hole c3 gather at point P3, the sewing needle 5 descends, and the second stitch is sewn. When the second needle is again raised above the upper button B1, the mechanisms operate so that the holes b1 and c1 gather again at the point P2, and the third stitch is sewn. By repeating the above operation several times, horizontal seams are formed between b1 and b3 and between c1 and c3. At the end of this seam, when the sewing needle 5 falls in the same hole b1 and hole c1 as the sewing start position and the thread gets entangled with the looper, the sewing needle 5 rises. Here, the spindle motor 14 temporarily stops. Further, the sewing thread is cut by the thread trimming means according to the setting.
[0060]
Next, each mechanism operates as follows to form a seam between b2-b4 (c2-c4).
E. The needle swing mechanism 11 and the button differential mechanism 70 do not move. By the lower Y feed mechanism 50, the lower button C1 moves by the distance w2, and the hole c2 indicated by the dotted line moves to the point P2.
Sa. By the upper Y feed mechanism 30, the upper button B1 moves by the distance W2, and the hole b2 indicated by the dotted line moves to the point P2.
As a result, the sewing needle 5, the hole b2, and the hole c2 gather at the point P2, and the spindle motor 14 starts to rotate here. After this, the operation continues in exactly the same way as between b1-b3 (c1-c3), a weft thread seam is formed between b2-b4 (c2-c4), and finally the sewing thread is cut by the thread trimming means. The sewing is finished.
[0061]
C. Cross stitch
In the case of cross stitching, as in the case of the vertical stitch and horizontal stitch, the above-mentioned operations (a) to (c) are performed by operating the preparation key from the initial state shown in FIG. When the pedal 105 is operated, the first needle falls to the point P2, the sewing needle 5 is raised, and the needle tip reaches above the upper button B1, and then each mechanism operates as follows.
Ii. By the needle swing mechanism 11, the sewing needle 5 at point P2 moves by the distance w1 and moves to point P3.
S. The lower Y feed mechanism 50 moves the lower button C1 by the distance w2, and the hole c4 indicated by the dotted line moves to the point P3.
C. The upper Y feed mechanism 30 moves the upper button B1 by the distance W2. Next, the button differential mechanism 70 moves the upper button B1 twice as long as the distance m1, and the hole b4 indicated by the dotted line moves to the point P3.
As a result, the sewing needle 5, hole b4, and hole c4 gather at point P3, the sewing needle 5 descends, and the second stitch is sewn. When the second needle is again raised above the upper button B1, the mechanisms operate so that the holes b1 and c1 gather again at the point P2, and the third stitch is sewn. By repeating the above operation several times, diagonal seams are formed between b1 and b4 and between c1 and c4. At the end of this seam, when the sewing needle 5 falls in the same hole b1 and hole c1 as the sewing start position and the thread gets entangled with the looper, the sewing needle 5 rises. Here, the spindle motor 14 temporarily stops. Further, the sewing thread is cut by the thread trimming means according to the setting.
[0062]
Next, each mechanism operates as follows to form a seam between b2-b3 (c2-c3).
Seo. The needle swing mechanism 11 and the button differential mechanism 70 do not move. The lower Y feed mechanism 50 moves the lower button C1 by the distance w2, and the hole c2 indicated by the dotted line moves to the point P2.
T. By the upper Y feed mechanism 30, the upper button B1 moves by the distance W2, and the hole b2 indicated by the dotted line moves to the point P2.
As a result, the sewing needle 5, the hole b2, and the hole c2 gather at the point P2, and the spindle motor 14 starts to rotate here. Thereafter, the operation continues in the same manner as between b1-b4 (c1-c4), an oblique seam is formed between b2-b3 (c2-c3), and finally the sewing thread is cut by the thread trimming means, Sewing is completed.
[0063]
The sewing machine 1 can cope with various button-sewn sewing in addition to the above (1). Hereinafter, the vertical movement of the sewing needle 5 including ON / OFF of the spindle motor 14 will be omitted, and the movement in the X and Y directions of the upper and lower buttons will be mainly described.
[0064]
(2) In case of 4 hole up button and 2 hole down button
A. Vertical eye
Also in this case, when the upper and lower buttons are set in the same manner as in (1), the initial positions where the center positions of the upper button B2 and the lower button C2 and the axis of the sewing needle 5 coincide with the point P1 as shown in FIG. 13B. It becomes a state. When the preparation key is operated in this state, the operation is as follows. In FIG. 13B, the symbols w2, W1, and W2 are the same as those in FIG. In this sewing, the needle swing mechanism 11 does not move at all.
[0065]
H. The lower button C2 is moved half the distance w2 by the lower Y feed mechanism 50, and the hole c1 is moved to the point P1.
Tsu. The upper button B2 is moved half the distance W2 by the upper Y feed mechanism 30, and is moved half the distance W1 by the button differential mechanism 70, and the hole b1 is moved to the point P1.
In this state (state indicated by the dotted line), the first stitch is dropped. And it operates as follows before the second stitch.
Te. The lower button C2 is moved by the distance w2 by the lower Y feed mechanism 50, and the hole c2 indicated by the dotted line is moved to the point P1.
G. The upper button B2 is moved by a distance W2 by the upper Y feed mechanism 30, and the hole b2 indicated by the dotted line is moved to the point P1.
The above process is repeated several times to form vertical seams between b1-b2 (c1-c2). Next, after the upper button B2 is moved by the distance W1 by the button differential mechanism 70, vertical seams are formed between b3-b4 (c1-c2) in substantially the same manner as the tate.
[0066]
B. Yokome
In this case, as shown in FIG. 14, the center of the upper button B3 and the lower button C3 and the sewing needle 5 are set in an initial state where they coincide at the point P1. In this sewing, the lower Y feed mechanism 50 does not move at all.
When the preparation key is operated in the initial state of FIG. 14, the operation is as follows.
Na. The needle swing mechanism 11 moves the sewing needle 5 to a point P2 that coincides with the center of the hole c1.
D. The upper button B3 is moved half the distance W2 by the upper Y feed mechanism 30, and further moved by the distance m1 of the upper and lower buttons by the button differential mechanism 70, and the hole b1 is moved to the point P2.
[0067]
In this state (state indicated by the dotted line), the first stitch is dropped. And it operates as follows before the second stitch.
Nu. By the needle swing mechanism 11, the sewing needle 5 moves by the distance w1 and moves to the point P3 that coincides with the center of the hole c2.
Ne. The upper button B3 is moved twice the distance m1 by the button differential mechanism 70, and the hole b3 is moved to the point P3.
The above process is repeated several times to form horizontal seams between b1 and b3 (c1 and c2). Next, after moving by the distance W2 by the upper Y feed mechanism 30, a horizontal seam is formed between b2-b4 (c1-c2) in substantially the same manner as in NU.
[0068]
In addition to the above (1) and (2), various buttons can be sewn.
For example, sewing the vertical or horizontal eye of the upper button B4 of the two holes (b1, b2) and the lower button C4 of the two holes (c1, c2) shown in FIG. 15A, as shown in FIG. It is also possible to sew the vertical or horizontal eye of the upper button B5 of the two holes (b1, b2) and the lower button C5 of the four holes (c1, c2, c3, c4).
[0069]
(3) In case of sticky stitching without down button
Even in the case of solid stitching without the lower button performed at position C of the lower plate 56, various buttons can be attached by freely driving each mechanism. For example, conventionally, the needle drop position on the fabric is separated as shown in FIG. However, in the sewing machine 1, the fabric is moved in the Y direction by the lower Y feeding mechanism 50 if it is a longitudinal eye in the Y direction, or the button is moved in the X direction by the button differential mechanism 70 if it is a lateral eye in the X direction. By doing so, it is possible to drop the needle drop position of the needle that has passed through the different button holes to one place on the fabric, and a good “V-shaped” stitch as shown in FIG. 19A is obtained.
[0070]
(4) In the case of rake sewing
In the case of rake sewing, as shown in FIG. 16A, the upper button B is set at the position A of the lower plate 56, and the cloth S is set in the cloth holding portion 60 with the tongue 57 folded. In the state set as shown in FIG. 16A, for example, if scoop sewing is performed for the first stitch, the upper Y feed mechanism 30 and the lower Y feed mechanism 50 are driven before the second needle drop. The needle is passed through a button hole different from that of the first stitch, and the stitch is not inserted into the fabric. By repeating this, vertical eyes can be formed in the Y direction.
In addition, in the case where a stitch is formed in the vertical direction on the upper button B of the four holes, the sewing needle 5 is moved by the needle swing mechanism 11 when shifting from the sewing of the first row L1 to the sewing of the second row L2. The upper button B is moved in the X direction by the button differential mechanism 70 so that the sewing needle 5 swung in an appropriate angle X direction and the sewing needle 5 swung by a predetermined angle can pass through the target button hole. As a result, the sewing needle 5 can be dropped at substantially the same point R on the fabric S in both the rake stitches in the first row L1 and the second row L2. Accordingly, a “V-shaped” stitch shape as shown in FIG. 19A is formed, and if this is followed by root winding sewing, a good-looking seam like hand-sewn as shown in FIG. 19B is formed. The
Note that, depending on the situation, when moving from the first row L1 to the second row L2, it may be driven only by the button differential mechanism 70.
[0071]
In the case of rake sewing, the needle is dropped into the fabric S as shown in FIG. 20 (a). For example, the fabric S is slightly moved in the Y direction by the lower Y feed mechanism 50 for one stitch. In FIG. 16B, the root yarn T can be passed through the back side of the fabric S to form a “force yarn”.
[0072]
(5) Shank button
When the shank button is sewn, the button head is rotated 90 degrees by the rotary cylinder 37 at the position B of the lower plate 56, and is sewn in the vertical state, that is, in the same state as the root winding. FIG. 17 schematically shows an initial state at the time of setting. In the initial state, the axis of the sewing needle 5, the shank part e of the shank button E, and the center of the lower button C6 coincide at the point P1. When the shank button E is sewn together with the four under-hole buttons C6, each mechanism operates as follows.
C. By the needle swinging mechanism 11, the sewing needle 5 moves by a half of the distance w1 (between c1 and c3, between c2 and c4) from the point P1 and moves to the point P2.
G. By the lower Y feed mechanism 50, the lower button C6 moves half the distance w2 (between c1 and c2, between c3 and c4), and moves the hole c1 to the point P2.
F. The shank button E is moved by a predetermined distance by the upper Y feed mechanism 30 so that the shank portion e is positioned between the holes c1 and c2 indicated by the dotted lines. Further, the button differential mechanism 70 moves half of the distance w1 so that the center of the shank portion e is located between the holes c1-c2.
[0073]
In the above state, the needle falls into the hole c1 and the first stitch is sewn, and then the lower Y feed mechanism 50 and the upper Y feed mechanism 30 operate and the sewing thread crosses over the shank portion e and the point P2 The needle falls into the hole c2. This is repeated to form vertical seams between c1 and c2.
Next, the sewing needle 5 moves from the point P2 by the distance w1 by the needle swing mechanism 11 and moves to the point P3. Thereafter, the operations after the above-mentioned heel are repeated in the same manner as between c1 and c2, and the warp stitches are formed between the holes c3 and c4.
In addition, the sewing machine 1 can freely sew the shank button and the bottom button of the two holes.
[0074]
(6) In case of backtack
Regardless of the type of sewing, such as rake stitching or sticky stitching, at the end of sewing, “stop stitching” is performed by dropping the needle into the same button hole several times. At that time, if it is desired to drop the needle at a different position with respect to the cloth, the needle can be dropped at a completely different location in the cloth while moving the cloth by the lower Y feed mechanism 50 while passing through the same button hole. .
[0075]
According to the sewing machine 1 described above, the upper button can be moved in the Y direction and the X direction by the upper Y feed mechanism 30 and the button differential mechanism 70. Further, the lower button and the fabric can be moved in the Y direction by the lower Y feeding mechanism 50. In addition, by using the needle swing mechanism 11 movable in the X direction, the lower button and the fabric can be moved in the X direction relative to the upper button. That is, the upper button and the lower button / fabric can be independently driven in the XY directions. Further, the upper button can be moved up and down by the button up-and-down moving mechanism 40, and the direction can be changed by 90 degrees by the rotating cylinder 37. By combining these mechanisms, it became possible to attach various buttons that look beautiful.
That is, as described above, sewing can be performed regardless of the type of upper and lower buttons, the number of holes, and the pitch.
[0076]
In addition, since the needle drop position of the fabric with respect to the upper button can be set freely, the needle drop position of the fabric can be set to almost one place for both rake sewing and solid stitching, A so-called “V-shaped” seam can be formed between the upper button and the fabric, and then a seam with a good texture can be formed by performing root winding sewing.
Conversely, if the sewing thread is thick and the needle drop occurs at the same location on the fabric, or if you want to stabilize the upper button against the fabric by the root thread, It is also possible to deliberately shift the needle entry position.
In rake root winding sewing, the length of the root thread is freely set by using the button up-and-down moving mechanism 40 at the time of rake sewing. From the bottom, the thread is linearly formed from directly under the upper button to the fabric, and the appearance is improved.
[0077]
Further, as described above, conventionally, in the rake sewing process, a force thread cannot be formed, and the cloth is penetrated at the time of root winding to replace the force thread. However, in the sewing machine 1, the force thread is used during the rake sewing process. Therefore, the upper button can have sufficient tensile strength.
[0078]
Furthermore, since the positions A, B, and C are provided on the lower plate 56, various buttons can be attached. Therefore, when a plurality of types of buttons are attached to one piece of clothing, a single sewing machine can be used, and costs can be reduced compared to purchasing a sewing machine for each type of button attachment as in the prior art. In addition, the operator can move the sewing product from the sewing machine to the sewing machine, and the amount of manual handling such as attachment replacement is reduced, and the work efficiency is improved.
When cycle sewing is selected on the operation panel 103, the lower plate 56 is driven by the lower Y feed mechanism 50, and the positions A, B, C are moved to a predetermined position below the sewing needle 5 in an appropriate order. This makes it possible to carry out the button sewing continuously, further improving work efficiency.
[0079]
As described above, the upper button and the lower button (cloth) can be moved independently in the XY directions, but the lower button uses a needle swing mechanism, so the conventional XY Compared with the case where two tables are provided, the overall weight can be reduced. In addition, although the swinging of the needle bar and the driving of the XY table are intermittent movements, the swinging of the needle bar can be driven at, for example, a maximum of 5000 rpm in the actual configuration, whereas the XY table is more driven. It can be driven only at a maximum load of about 2700 rpm. Therefore, it is possible to operate at a higher speed than using an XY table, and work efficiency is improved.
Further, since the lower Y feed mechanism 50 is configured by belt driving, it can be moved for a long distance, and movement between positions A, B, and C is facilitated.
[0080]
In the above embodiment, the needle swing driving means for swinging the needle bar in a plane orthogonal to the longitudinal direction of the main shaft has been described. However, the needle bar is swung in a plane parallel to the longitudinal direction of the main shaft. May be.
Further, the present invention is not limited to the above-described embodiment, and it is needless to say that specific shapes and structures can be appropriately changed.
For example, in the above example, the front button is the upper button and the back button such as the force button is the lower button, but it may be configured to be installed upside down.
Further, specific structures such as an upper Y feed mechanism, a button differential mechanism, and a lower Y feed mechanism that are characteristic of the present invention are not limited to the above-described embodiments. For example, although the lower Y feed mechanism uses belt drive, it may be constituted by a gear mechanism such as a rack and a pinion. Conversely, the upper Y feed mechanism and the button differential mechanism may be configured by belt drive, or may have a gear structure different from the above embodiment.
Although the chuck portion 90 is opened and closed by a manual lever, the button may be configured to be chucked and released using a driving source such as a cylinder.
[0081]
Further, the sewing order of the button holes is not limited to the order described in FIGS. 13 to 17 and can be changed as appropriate. Further, the amount of movement of the upper button and the lower button may be appropriately changed if the relationship between the hole pitches of the upper and lower buttons is different, for example, the hole pitches of the upper button and the lower button are exactly the same.
[0082]
Further, in the present invention, the button differential mechanism is not necessarily provided. FIG. 18 shows a chuck unit 200 that is not provided with a button differential mechanism. In FIG. 18, the same members as those in the chuck unit 71 of FIG. For example, when it is not necessary to drive the upper button B in the X direction, it is useful because the weight applied to the arm portion 4 can be reduced by configuring as shown in FIG.
[0083]
【The invention's effect】
According to the first aspect of the present invention, the sewing needle swings in a plane parallel or perpendicular to the longitudinal direction of the main shaft by the needle swing driving means. Further, the upper button can be moved in the same direction as the cloth feeding direction by the first button feed driving means and in the same direction as the needle swinging direction by the second button feed driving means orthogonal thereto. Further, the lower button and the fabric can be moved in a direction orthogonal to the needle swinging direction by the cloth feed driving means. If the swinging motion of the sewing needle is used, the lower button and the fabric can be moved in the direction orthogonal to the cloth feed driving means relative to the upper button. That is, the upper button and the fabric (lower button) can be driven in two directions orthogonal to each other in the horizontal plane.
Therefore, by combining these driving means, the relative positional relationship between the upper button and the fabric (lower button) can be freely changed, and various buttons can be attached which was impossible in the past.
[0084]
In addition, as described above, the upper button and the fabric (lower button) can be freely moved in two directions orthogonal to each other, but the lower button uses a needle swing mechanism, so that Compared with the case where two XY tables are provided and driven, the overall weight can be reduced. In addition, since the needle bar swings and the XY table moves only when the needle is positioned above the needle plate, it is an intermittent motion anyway. Dynamic motion is faster than driving the table, enabling high-speed operation and high work efficiency.
[0085]
According to the second aspect of the present invention, the sewing needle swings in a plane parallel or perpendicular to the longitudinal direction of the main shaft by the needle swing driving means. The upper button can be moved in the same direction as the cloth feeding direction or the needle swinging direction by the first button feed driving means or the second button feed driving means. Further, the lower button and the fabric can be moved in a direction orthogonal to the needle swinging direction by the cloth feed driving means.
In other words, the upper button, the fabric (lower button), and the sewing needle can be driven in one direction. By combining these driving means, the relative positional relationship between the upper button and the fabric (lower button). Can be freely changed to some extent, and various buttons can be attached which was impossible in the past.
[Brief description of the drawings]
FIG. 1 is a diagram showing an outline of an appearance of a sewing machine which is an example of a root winding button sewing machine according to the present invention, together with a control block diagram.
FIG. 2 is a perspective view showing a needle up / down movement mechanism and a needle swing mechanism.
FIG. 3 is a perspective view showing drive motors for the needle up-and-down movement mechanism and the needle swing mechanism in FIG. 2;
4 is a perspective view showing a main part of the needle up-and-down moving mechanism and the needle swinging mechanism of FIG. 2;
FIG. 5 is a perspective view mainly showing an upper Y feed mechanism and a chuck unit.
FIG. 6 is a perspective view mainly showing an upper Y feed mechanism and a chuck unit.
FIG. 7 is a perspective view showing a chuck unit.
FIG. 8 is a perspective view showing the bottom side of the chuck unit.
FIG. 9 is a perspective view showing the chuck unit with the motor unit detached.
FIG. 10 is a perspective view showing a lower plate and a lower Y feed mechanism.
FIG. 11 is a perspective view showing the lower Y feed mechanism with the lower plate removed.
FIG. 12 is a perspective view showing the bottom side of the lower Y feed mechanism.
FIG. 13A is a diagram for explaining the sewing of the four-hole up button and the four-hole-down button, and FIG. 13B is the sewing of the four-hole up button and the two-hole down button ( It is a figure for demonstrating (vertical eye).
FIG. 14 is a diagram for explaining sewing (horizontal stitches) of a four-hole up button and a two-hole down button.
15A is a diagram illustrating a two-hole up button and a two-hole down button, and FIG. 15B is a diagram illustrating a two-hole up button and a four-hole down button.
FIG. 16A is a perspective view showing a state of rake stitching, and FIG. 16B is a side view schematically showing a force thread.
FIG. 17 is a view for explaining sewing of a shank button and a four-hole lower button.
FIG. 18 is a perspective view showing another example of the chuck unit.
FIG. 19 is a diagram schematically showing a state in which an upper button is sewn on a cloth.
FIGS. 20A and 20B are diagrams for explaining a process of sewing with a root winding button, in which FIG. 20A shows rake sewing and FIG. 20B shows root winding sewing.
[Explanation of symbols]
1 Sewing machine (sewing machine with root winding button)
5 Sewing needle
7 Spindle
9 Needle bar
10 Needle up / down movement mechanism (needle up / down drive means)
11 Needle swing mechanism (needle swing drive means)
30 Upper Y feed mechanism (first button feed drive means)
40 button vertical movement mechanism
46 Button rotation mechanism (rotating means)
50 Lower Y feed mechanism (cloth feed drive means)
53 Timing Belt
56 Lower plate (cloth feed plate)
57 tongue
70 button differential mechanism (second button feed drive means)
71, 200 Chuck unit
72 Differential motor
101 Electrical box
102 CPU (control means)
102a memory
103 Operation panel
B, B1-B5 Up button
C1-C6 Down button
E Shank button
S Cloth (Sewing product)

Claims (8)

Needle up / down driving means for driving a needle bar having a sewing needle at the lower end portion up and down by a main shaft installed substantially horizontally;
Needle swing drive means for swinging the needle bar in a plane parallel or perpendicular to the longitudinal direction of the main shaft;
A cloth feed driving means for driving a cloth feed plate for placing the lower button and the sewing product on the upper surface in a direction orthogonal to the needle swinging direction of the needle swing driving means;
First button feed driving means for driving an upper button gripping part for gripping the upper button substantially horizontally in a direction parallel to the cloth feed direction of the cloth feed drive means;
Second button feed driving means for driving the upper button gripper in a direction orthogonal to the drive direction of the first button feed drive means and parallel to the needle swing direction;
A root winding button-attached sewing machine comprising control means for controlling the driving means. Needle up / down driving means for driving a needle bar having a sewing needle at the lower end portion up and down by a main shaft installed substantially horizontally;
Needle swing drive means for swinging the needle bar in a plane parallel or perpendicular to the longitudinal direction of the main shaft;
A cloth feed driving means for driving a cloth feed plate for placing the lower button and the sewing product on the upper surface in a direction orthogonal to the needle swinging direction of the needle swing driving means;
First button feed driving means for driving the upper button gripping part for gripping the upper button substantially horizontally in a direction parallel to the cloth feeding direction of the cloth feed driving means, and the driving direction of the first button feed driving means for the upper button gripping part Any one of the second button feed driving means for driving in a direction perpendicular to the direction and parallel to the needle swing direction;
A root winding button-attached sewing machine comprising control means for controlling the driving means. The cloth feeder is
A cloth holding section that holds the sewing product in a folded state and enables rake sewing;
A lower button holding portion that holds the lower button under the sewing product and enables sewing with the lower button;
On the upper surface of the sewing product, there is provided an upper button sticking portion that enables sticking sewing to stick the upper button.
2. The cloth feed driving means is capable of driving the cloth feed plate so that each of the cloth holding portion, the lower button holding portion, and the upper button sticking portion is positioned substantially below the sewing needle. Or the root winding button sewing machine of 2. Storage means for storing a cycle stitching program for continuously sewing two or more different types of button-sewn stitches including rake stitching, lower button stitching, and solid stitching;
4. The root winding button sewing machine according to claim 3, wherein the control means controls each of the driving means so as to perform cycle sewing in accordance with the cycle sewing program. The bottom winding button attachment according to claim 1 or 2, characterized in that it is possible to sew a lower button with a combination of an upper button and a lower button in which at least one of the number of holes, the pitch of the holes, and the arrangement of the holes is different. sewing machine. The stitching position of the sewing needle that passes through the button hole of the upper button to the sewing product is a stitch that concentrates on one point, a stitch that concentrates on two predetermined points, and a stitch that has three or more predetermined points The root winding button sewing machine according to claim 1, wherein each of the sewing machines can be formed. The present invention is characterized in that needle stitching can be performed at a plurality of arbitrary positions on a sewing product without being limited by the size of the button hole in the backstitching in which the sewing needle is passed through the same button hole a plurality of times continuously. Item 3. A sewing machine with a button-wound button according to item 1 or 2. The root winding button-attached sewing machine according to any one of claims 1 to 7, further comprising rotating means for rotating the upper button gripping part by 90 degrees so that the upper button is vertically supported.

Images