KR102266034B1 - Bobbin thread introduction device and sewing machine thereof - Google Patents

Abstract

The bobbin thread introducing device of the present invention is mounted in a sewing machine, and includes two operation modules, a clamp module and two moving modules. One of the operation modules may be provided with a blade, and one of the operation modules may drive the bobbin to wind the bobbin thread. The clamp module in the clamping position can clamp the bobbin thread and move back and forth on two different paths via the two moving modules, thus holding the clamp module holding the bobbin thread in contact with the blade. When the bobbin thread comes into contact with the bobbin case, the other operating module rotates, which causes the rotating bobbin case to guide the bobbin thread into the thread guiding slot of the bobbin case. By doing so, the two operation modules, the clamp module and the two moving modules can jointly wind the bobbin thread on the bobbin as well as introduce the bobbin thread.

Description

Bobbin thread introduction device and its sewing machine {BOBBIN THREAD INTRODUCTION DEVICE AND SEWING MACHINE THEREOF}

The present invention relates to an apparatus for introducing a bobbin thread applied to a sewing machine, and in particular, it is possible to wind a bobbin thread on a bobbin and to use the bobbin thread as a thread guiding slot of a bobbin case. It relates to a bobbin introduction device capable of being guided.

When using a lockstitch principle sewing machine, whether it is a full-rotary rotary hook or a semi-rotary swing hook, there is a bobbin that can wind the bobbin thread. . In addition, most sewing machines using the lock stitch principle have a bobbin case for accommodating the bobbin.

However, in order to increase the rotation speed of the sewing machine, the capacity of the bobbin for accommodating the bobbin thread cannot be too large, while the length of the bobbin thread is relatively limited, and therefore the bobbin is frequently should be replaced; In addition, when the bobbin thread is replaced, the sewing machine has to stop the sewing operation, and the operator has to manually replace the bobbin thread, so it is difficult to increase the production efficiency.

In order to overcome the above-mentioned disadvantages, there is an automatic bobbin changing device in the sewing machine industry. When it is detected that the bobbin thread wound on the bobbin has fallen off, the automatic bobbin changing device will simultaneously separate the bobbin case and the bobbin from the rotary hook. Accordingly, in order to achieve the function of automatically replacing the bobbin, both the bobbin case and the bobbin are separated from the hook, and then another set of the bobbin case and the bobbin full of bobbin threads are assembled to the rotary hook at the same time.

However, although the above-described automatic bobbin changing device can separate the bobbin whose bobbin thread is almost gone from the rotary hook, the above-described automatic bobbin changing device allows the operator to wind the bobbin thread on the bobbin and insert the bobbin thread into the thread guiding slot of the bobbin case It cannot help to introduce, therefore, the operator needs to manually wind the bobbin thread on the bobbin and manually guide the bobbin thread into the thread guiding slot of the bobbin case, which causes time consuming for the operator.

The main object of the present invention is not only to wind the bobbin thread on the bobbin, but also to introduce the bobbin thread into the thread guiding slot of the bobbin case, thereby automatically mounting the bobbin thread on the rotary hook to improve the production efficiency of the sewing machine. .

In order to achieve the above object, the present invention relates to a bobbin thread introducing device, wherein the bobbin thread introducing device is capable of mounting a bobbin thread to a bobbin and a bobbin case, and is assembled to a sewing machine; the bobbin thread introducing device includes a first operation module, a bobbin thread clamping mechanism and a second operation module, the sewing machine has a sewing machine body and a bobbin changing device, and the sewing machine body has a rotary hook; The bobbin changing device can be assembled to the sewing machine body and the bobbin can be assembled from the rotary hook to the bobbin thread introducing device.

The first operation module has a first transmission member and a first driving source operable to rotate the first transmission member, and the bobbin is driven to rotate synchronously by the first transmission member, such that the bobbin yarn is the bobbin to wrap in

The bobbin thread clamping mechanism includes a clamp module, a first moving module and a second moving module. the clamp module is positioned in the clamping position to clamp the bobbin seal, the first movement module is operable to move the clamp module along a first path from the clamping position to the first ready position, and the second movement module is the clamp module may be driven to move from the first ready position to the first guiding position along a second path intersecting the first path.

The second operation module has the second transmission member and a second driving source operable to rotate the second transmission member. The bobbin case is driven to rotate synchronously by the second transmission member, so that the rotating bobbin case can introduce the bobbin yarn into the yarn guiding slot formed on the bobbin case.

In this embodiment, the first transmission member is provided with a blade; When the clamp module moves from the first ready position to the first guiding position, the bobbin thread is in contact with the blade, and when the clamp module moves to the first guiding position, the first transmission member is driven to rotate to cut the bobbin thread do.

The bobbin yarn introducing device further has a yarn releasing mechanism, the yarn releasing mechanism having a release lever and a release driving source; The ejection lever is spaced from the first transmission member and the ejection drive source can drive the ejection lever to move closer to or away from the first transfer member, so that when the ejection lever pushes the blade, , the blade moves relative to the first transmission member, whereby the clamping space between the blade and the first transmission member exhibits an open state into which the bobbin seal enters.

Further, in the bobbin yarn introducing device, a bobbin yarn control mechanism is further provided between the first operation module and a thread gripper, and the bobbin yarn control mechanism is connected to the adjustable drive source capable of generating power and the adjustable drive source. having an adjustment member driven to move closer to or away from the bobbin yarn by As the adjustment member approaches the bobbin seal, the adjustment member may restrict the bobbin seal close to the clamp module, which causes the clamp module to clamp the bobbin seal in the clamping position.

In a preferred embodiment, the first moving module is coupled to the second moving module, and when the second moving module drives the clamp module to move along the second path, the first moving module moves simultaneously. The second moving module drives the first moving module and the clamp module to move away from the first guiding position, which causes the clamp module to move to the second ready position along a third path parallel to the second path. ; The first moving module drives the clamp module to move from the second ready position to the second guiding position along a fourth path parallel to the first path, wherein the bobbin thread is formed on a hook arm formed on the bobbin case. ) to come into contact with

Further, when the clamp module is in the second guiding position, the second transmission member rotates to introduce the bobbin thread into the thread hole formed on the hook arm. In this embodiment, the bobbin case further has a thread blocking piece capable of confining the bobbin thread to the thread hole; The yarn blocking piece has an elastically changeable elastic arm, which is positioned on one side of the hook arm to prevent the bobbin yarn from being separated from the yarn hole.

Finally, the first moving module has a jaw transmission member connected to the clamp module and a clamp drive source connected to the jaw transmission member; The jaw transfer member and the clamp drive source are connected together to an avoidance unit, and when the clamp module moves to the clamping position along the first path, the avoidance unit is disposed between the bobbin case and the jaw transfer member, the clamping drive source or the clamp module. can change the relative position of at the same time, so that when the clamp module moves to the clamping position along the first path, the clamp module does not contact the bobbin through the avoidance unit.

In a preferred embodiment, the avoiding unit comprises a guide wheel, an assembling plate, a swinging plate, a holding member and a roller. the guide wheel is coupled to the jaw transfer member, and the assembly plate has a curved guide rail in contact with the guide wheel; The swing plate is assembled to the clamp drive source and is pivotally connected to the assembly plate; The holding member is positioned between the building plate and the swing plate, and can generate a holding force acting on the swing plate, which causes the swing plate to swing relative to the building plate through the holding force, which causes the guide wheel to bend. in constant contact with the old guide rails; Also, the roller may be brought into contact with the jaw transfer member, and when the roller comes into contact with the first moving module, the swing plate swings to drive the guide wheel away from the curved guide rail.

Finally, the clamp module has a movable clamp that can be repositioned and a fixed clamp fixed to the jaw transfer member, one of the movable clamp and the fixed clamp has a clamping groove, and the movable clamp and the fixed clamp the rest of the clamps have clamping blocks; When the clamp module clamps the bobbin seal, the clamping block moves into the clamping slot, so that the clamping block and the clamping slot jointly clamp the partial length of the bobbin seal.

The present invention is characterized in that the blade is provided on the first moving module, and the first moving module can be driven so that the bobbin winds the bobbin thread. The clamp module in the clamping position is capable of clamping the bobbin thread and moves to the guiding position via the first and second moving modules, so that the clamp module holds the bobbin thread in contact with the blade. Due to this, when the bobbin yarn comes into contact with the bobbin case, the second moving module rotates, which causes the rotating bobbin case to guide the bobbin yarn into the yarn guiding slot formed on the bobbin case. By doing so, the first and second operation modules, the clamp module as well as the first and second moving modules can jointly wind the bobbin thread on the bobbin and introduce the bobbin thread into the thread guiding slot of the bobbin case. Thereby, it is possible to shorten the working time of installing the bobbin seal on the rotary hook.

The accompanying drawings are intended to provide a further understanding of embodiments of the present disclosure. The drawings form a part of the present disclosure and, along with the literal description, serve to explain the principles of embodiments of the present disclosure. Obviously, the drawings described below are merely some embodiments of the present disclosure, and a person of ordinary skill in the art may obtain other drawings according to these drawings without creative efforts. In the drawings:
1 is a view showing a perspective view of an automatic bobbin take-up sewing machine according to a first preferred embodiment of the present invention;
2 is a view showing an exploded perspective view of an automatic bobbin take-up sewing machine according to a first preferred embodiment of the present invention;
Fig. 3A is an exploded perspective view of a bobbin module;
3B is a diagram illustrating a bobbin module according to another embodiment;
Fig. 4 is a view showing an exploded perspective view of replacement of the bobbin of Fig. 2;
Fig. 5 is a view showing an exploded perspective view of the bobbin yarn introducing device of Fig. 2;
Fig. 6 is an exploded perspective view of the bobbin module operating mechanism of Fig. 5;
7 is a diagram showing a cross-sectional view of a bobbin module operating mechanism;
Fig. 8 is a view showing a bobbin case mounted on a third transmission member;
Fig. 9 is an exploded perspective view of the bobbin seal clamping mechanism of Fig. 5;
Fig. 10 is an exploded perspective view of the yarn release mechanism of Fig. 5;
Fig. 11 is an exploded perspective view of the bobbin yarn control mechanism of Fig. 5;
Fig. 12 is a view showing a perspective view of the residual bobbin yarn removing device of Fig. 2;
Fig. 13 is a view showing a bobbin mounted to a first transmission member;
14A is a view showing a rotary hook and a bobbin module operating mechanism that are separately assembled to a bobbin module;
Fig. 14B is a view showing the movable frame moving in a direction approaching the rotary hook;
14C is a view showing a first jaw assembly clamping a first bobbin module;
14D is a view showing a second jaw assembly clamping a second bobbin module;
Fig. 14E is a view showing the movable frame moving in a direction away from the rotary hook;
Fig. 14f is a view showing a movable frame rotating in a clockwise direction;
Fig. 14G is a view showing the movable frame re-closed to the rotary hook;
14H is a view showing the second jaw assembly loosening the second bobbin module;
Fig. 14i is a view showing the first jaw assembly positioned directly in front of the bobbin module operating mechanism;
14J is a view showing a positioning protrusion entering a positioning groove;
14K shows a latch clip clamping an annular groove into a positioning groove;
14L is a diagram illustrating a bobbin of a first bobbin module coupled to a first transmission member via an alignment mechanism;
Fig. 15A is a view showing a state of separation between the bobbin case and the bobbin;
Fig. 15B is a view showing the cutter in a cutting position;
15C is a diagram illustrating an inhalation mechanism according to an aspect of another embodiment;
Fig. 15D is a view showing a local cross-sectional view of Fig. 15C;
Fig. 16A is a view showing a bobbin on which a bobbin thread is wound;
Fig. 16B is a diagram showing the bobbin yarn control mechanism for controlling the position of the bobbin yarn;
Fig. 16c shows the clamping module moving to the position of the clamping position;
Fig. 16d is a view showing a clamp module clamping a bobbin seal;
Fig. 16E is a view showing the clamp module moving to the first ready position;
16f is a diagram showing a yarn release mechanism clamping a bobbin yarn;
Fig. 16G is a view showing the clamp module moving to the first guiding position;
Fig. 16H is a view showing a cutter for cutting a bobbin thread;
17A is a view showing an assembly state between the bobbin case and the bobbin;
17B is a view showing a wound bobbin yarn being introduced into a yarn guiding slot;
17C is a view showing the clamp module moving to the second ready position;
17D is a view showing a first jaw transfer member in contact with a roller;
Fig. 17E is a view showing the clamp module moving to the second guiding position;
17f is a view showing a wound bobbin yarn being introduced into a yarn hole;
Fig. 18 is a diagram showing a bobbin module operating mechanism according to a second preferred embodiment; And
19 is a diagram showing a bobbin module operating mechanism according to a third preferred embodiment.

In order to clearly understand the above objects, features and advantages of the present disclosure, the present disclosure will be described below in detail with reference to the accompanying drawings and specific embodiments.

Reference is made to Figures 1 and 2 . In the first preferred embodiment, the automatic bobbin take-up sewing machine of the present invention is used together with the bobbin module 50 (shown in FIG. 3), and the sewing machine body 10, the bobbin changing device 20, the bobbin thread introducing device ( 30) and a residual bobbin yarn removal device 40 . Referring to FIG. 3 , the bobbin module 50 includes a bobbin 51 that can wind a bobbin thread 60 (shown in FIG. 14A ) and a bobbin case 52 that can be mounted on the bobbin 51 . ; The bobbin 51 has a spool member 511 and two stop plates 512; A partial section of the spool member 511 is set as a first winding 511a, and the remaining section of the spool member 511 is set as a second winding 511b having a larger outer diameter than the first winding 511a. and the two stop plates 512 are spaced apart and formed in the first winding portion 511a and the second winding portion 511b, respectively, and thus, the spool member 511 is disposed between the two stop plates 512. is located; Further, the spool member 511 and the two stop plates 512 jointly form a winding space 513 capable of accommodating the bobbin thread 60 (shown in Fig. 14A). As shown, the spool member 511 is concave to form a spool groove 511c connected to the winding space 513 , and one of the stop plates 512 is a limiting groove connected to the winding space 513 . concave to form 512a; The spool groove 511c is connected with the limiting groove 512a, so that the spool groove 511c and the limiting groove 512a together form a through space (indentation) along the surface contour of the bobbin 51. 514) is formed. However, the fact that the spool member 511 of the bobbin 51 has the first winding portion 511a and the second winding portion 511b is for convenience of description. 3B, a limiting flange 511d extends outwardly from the spool member 511, and the limiting flange 511d is near the stop plate 512 in which the limiting groove 512a is formed. have.

As shown in Fig. 3A, the bobbin case 52 has a housing 521 of a hollow structure; A bobbin shaft 522 having a hollow structure is disposed inside the housing 521 . A closed end 523 and an open end 524 are formed at opposite ends of the housing 521, respectively; An accommodation space 525 for accommodating the bobbin 51 is formed between an inner edge of the housing 521 and an outer edge of the bobbin shaft 522 . A thread guiding hole 526 is formed through the housing 521 and is connected to the accommodation space 525 ; A thread guiding slot 527 connected to the receiving space 525 is formed by concave the housing 521 from the open end 524 toward the closed end 523 . In this embodiment, the housing 521 is a clamping elastic piece that allows the bobbin thread 60 (shown in FIG. 17B ) to be guided from the thread guiding slot 527 to the thread guiding hole 526 . piece 528 , and a hook arm 529 is formed by extending outwardly from the housing 521 ; A guiding opening 528a is provided on one side of the clamping elastic piece 528, and the outer edge of the hook arm 529 is concave to form a seal hole 529a. In addition, a thread blocking piece 530 assembled on the closed end 523 of the housing 521 may limit the bobbin seal 60 (shown in FIG. 17B ) to the thread hole 529a. and the seal blocking piece 530 has an elastically deformable elastic arm 530a near the seal hole 529a, and the elastic arm 530a prevents the bobbin seal 60 from leaving the seal hole 529a. It is located on one side of the hook arm 529 so as to

Reference is again made to FIG. 2 . The sewing machine body 10 has a base 11 (the figure shows only a specific part of the base 11), and the base 11 includes a lower shaft (not shown in the drawing) disposed horizontally. and the lower shaft can be driven to rotate the rotary hook 12 installed inside the base 11; The work table 13 is disposed on the base 11 , the base 11 is connected to a fixing frame 14 , and the base 11 is a thread gripper attached to the fixing frame 14 . ) (15).

See Figures 2 and 4. The bobbin changing device 20 is located in front of the rotary hook 12, and the bobbin module moving assembly 21, the movable frame 22, the first jaw assembly 23 and the second jaw assembly (second) jaw assembly) and a rotary hook (12). The bobbin module moving assembly 21 is configured to drive the movable frame 22 to selectively move the moving frame 22 closer to or away from the bobbin module rotating assembly 25, and capable of generating actuating power. It has a movement driving source 211 located there and a transmission rod 212 assembled to the movement driving source 211 . In this embodiment, the moving driving source 211 is connected to the movable frame 22 , and the transfer rod 212 is fixed to the fixed frame 14 of the sewing machine body 10 , and thus the moving driving source 211 . ) generates the moving power, the moving drive source 211 moves integrally in the axial direction along the transfer rod 212 . Accordingly, it is possible to generate a movement such that the movable frame 22 approaches the rotary hook 12 or away from the rotary hook 12 .

The movable frame 22 has a first connecting end 221 and a second connecting end 222 spaced apart from the first connecting end 221 . The assembly connected to the moving drive source 211 is disposed between the first connecting end 221 and the second connecting end 222 ; The first jaw assembly 23 has a first jaw connecting base 231 formed of two symmetrical plate pieces; Article 1 connection base 231 is assembled with an immovable first fixed jaw 232 , and a first pivoting portion 231a is spaced apart from the first fixed jaw 232 . is placed on the side; The first fixed jaw 232 is fixedly coupled to the first connecting end 221 , and the first pivoting portion 231a is pivotally pivotally coupled to the first movable jaw 233 capable of swinging. ) are connected; In addition, the first movable jaw 233 has a first clamping portion 233a (shown in FIG. 14C ), and the first jaw driver 234 coupled to the movable frame 22 is a first assembled to one end of the first movable jaw 233 spaced apart from the clamping portion 233a; The first clamping portion 233a selectively moves closer to or away from the first fixed jaw 232 , the first jaw driver 234 engages the first movable jaw 233 . It can be driven to swing back and forth.

Article 2 assembly 24 is coupled to the second connection end 222 of the movable frame 22, Article 2 connection base 241 having the same structure as Article 1 connection base 231, the first fixed A second fixed jaw 242 having the same structure as the jaw 232, a second movable jaw 243 having the same structure as the first movable jaw 233 (shown in Fig. 14D), and a first jaw driver 234 ) and Article 2 driver 244 having the same structure. In addition, the Article 2 connecting base 241 , the second fixed jaw 242 , the second movable jaw 243 and the Article 2 driver 244 are connected to each other in the same manner as the Article 1 assembly 23 . . Accordingly, a description of the structure of the second set assembly 24 is omitted below.

The bobbin module rotation assembly 25 has a rotation drive source 251 and a transmission module 252 . The rotational drive source 251 can generate rotational power, and is fixed to the fixed frame 14 of the sewing machine body 10; The transfer module 252 is positioned between the rotational drive source 251 and the transfer rod 212 of the bobbin module moving assembly 21 ; The transmission module 252 has a first transmission gear 252a assembled to the rotational drive source 251 and a second transmission gear 252b meshing with the first transmission gear 252a; The second transmission gears 252a are assembled to the transmission rod 212 in a coaxial manner, whereby the first and second transmission gears 252a, 252b are when the rotational drive source 251 can generate rotational power. They can drive the movable frame 22 to rotate about the transfer rod 212 as the axial center. In addition, since the moving driving source 211 of the bobbin module moving assembly 21, and the first and second set assemblies 23 and 24 are all connected to the movable frame 22, when the movable frame 22 rotates The first and second jaw assemblies 23 and 24 rotate synchronously.

See Figures 2 and 5. The bobbin thread introducing device 30 is assembled to the fixed frame 14 of the sewing machine body 10, the bobbin module operating mechanism 31, the bobbin thread clamping mechanism 32, the thread releasing mechanism 33, and the bobbin thread control mechanism. (34). Reference is made to FIGS. 2 to 7 . The bobbin module operation mechanism 31 includes a first operation module 311 , a second operation module 312 , a third operation module 313 , and a synchronization module 314 . As shown in the figure, the first operation module 311 has a first driving source 3111 and a first transmission member 3112; The first driving source 3111 may be assembled to the fixed frame 14 of the sewing machine body 10 , and may generate rotational power to drive the first transmitting member 3112 to perform a rotational operation. The first transmission member 3112 is disposed coaxially along a motion axis L parallel to the first transmission member 3112, and one end of the first transmission member 3112 is connected to a connecting plate 3112a. to form; A blade 3112b is mounted on the first transmission member 3112 under the connection plate 3112a. The blade 3112b is made of an elastic material, and an edge portion 3112c (shown in FIG. 10) under the connecting plate 3112a as well as the connecting portion 3112d (shown in FIG. 10) behind the connecting plate 3112a. has In this embodiment, the operation axis L overlaps the axis of the first transmission member 3112 , and the first driving source 3111 is first transmitted through a first interlocking module 3113 . It is connected to the member 3112 , and the first interlocking module 3113 is assembled to the first driving belt pulley 3113a and the first transmission member 3112 assembled to the first driving source 3111 . and a first driven belt pulley 3113b, wherein the first driven belt pulley 3113a is assembled with a first belt 3113c connected to the first driven belt pulley 3113b.

The second operation module 312 has a second driving source 3121 capable of generating rotational power and a second transmission member 3122 spaced apart from the first transmission member 3112 . The second driving source 3121 is assembled to the fixed frame 14 of the sewing machine body 10, and is connected to the second transmission member 3122 through the second interlocking module 3123, and thus, the second driving source ( 3121 may drive the second transmission member 3122 to perform a rotation operation through the second interlocking module 3123; The second transmission member 3122 is disposed coaxially to the first transmission member 3112 such that the axis of the second transmission member 3122 overlaps the operation axis L. As shown in the drawing, the second interlocking module 3123 includes a second driving belt pulley 3123a assembled to the second driving source 3121 and a second driven belt pulley assembled to the second transmission member 3122 ( 3123b), the second drive belt pulley 3123a is connected to the second driven belt pulley 3123b via the second belt 3123c.

The third operation module 313 has a second drive source 3131 capable of generating movement power and a third transmission member 3132 coaxially disposed on the operation axis L. The third driving source 3131 is configured such that the third interlocking module 3133 is mounted, and moving the third interlocking module 3133 away from the third transmitting member 3132 or in contact with the third transmitting member 3132 . drive to; the two ends of the third transmission member 3132 pass through the first transmission member 3112 and the second transmission member 3122, respectively; The fact that the third transmission member 3132 is movable relative to the first and second transmission members 3112 and 3122 means that the third transmission member 3132 moves to the first and second transmission members 3112 and 3122. make it possible to assemble In the present embodiment, when the third driving source 3131 emits the third interlocking module 3133 to move away from the third transmitting member 3132 , the third driving source 3131 together with the second transmitting member 3122 . A pressing block 3132a connected to the transmission member 3132 presses a resetting member 3134 positioned between the second transmission member 3122 and the third transmission member 3132; Accordingly, the resetting member 3134 is pressed like a spring, creating a restoring force 3134a acting on the pressing block 3132a, and the magnitude of the restoring force 3134a is smaller than the moving power of the third driving source 3131 . Accordingly, when the third driving source 3131 generates movement power to drive the third interlocking module 3133 to push the third transmission member 3132 , the third driving source 3131 moves the motion axis L ) to overcome the restoring force 3134a of the resetting member 3134 to push the third transmission member 3132 to move linearly along make it go away

The synchronization module 314 is positioned between the second transmission member 3122 and the third transmission member 3132 , and may cause the second transmission member 3122 and the third transmission member 3132 to rotate at the same time. As shown in the drawing, the synchronization module 314 includes a synchronization groove 3141 formed on the second transmission member 3122 and a synchronization protruding pillar formed on the third transmission member 3132 . ) (3142). Synchronous groove 3141 exhibits an elongate shape; The synchronization protruding pillar 3142 may pass through the synchronization groove 3141 , and may move in the axial direction within the synchronization groove 3141 while the third transmission member 3132 moves.

See FIG. 8 . The bobbin case 52 of the bobbin module 50 is mounted on the third transmission member 3132 of the third operation module 313 , and the limiting assembly 315 is connected to the bobbin case 52 and the third It is disposed between the transfer members 3132 . The restriction assembly 315 includes an anti-displacement unit 3151 and a bobbin case 52 that can limit the bobbin case 52 from having axial movement relative to the third transfer member 3132 . has an anti-rotation unit 3152 that can limit rotation relative to the third transmission member 3132 . As shown in the figure, the displacement prevention unit 3151 is provided with an annular groove 3151a, a latch clip 3151b and a latch 3151c. An annular groove 3151a is formed on a portion of the third transmission member 3132 protruding from the first transmission member 3112, and the latch clip 3151b and the latch 3151c are pivotally connected to each other. Also, the latch clip 3151b and the latch 3151c are both mounted to the closed end 523 of the bobbin case 52 . In this embodiment, the latch clip 3151b and the latch 3151c both belong to the components of the bobbin case 52, and when the bobbin case 52 is mounted on the third transmission member 3132 , the third transmission member 3132 passes through the bobbin shaft 522 of the bobbin case 522 , so that the partial section of the third transmission member 3132 is outward from the closed end 523 of the bobbin case 52 . is protruded into As a result, in order to limit the bobbin case 52 from having axial movement, the latch 3151c can be snapped into the annular groove 3151a.

As shown in the figure, the anti-rotation unit 3152 has a positioning protrusion 3152a and a positioning groove 3152b. The positioning protrusion 3152a is formed on the third transmission member 3132 of the third operation module 313 and is spaced apart from the annular groove 3151a of the displacement prevention unit 3151; The positioning groove 3152b is formed on the bobbin shaft 522 of the bobbin case 52; When the bobbin case 52 is mounted on the third transmission member 3132 , the third transmission member 3132 passes through the bobbin shaft 522 of the bobbin case 52 ; Accordingly, in order to restrict the bobbin case 52 from rotating, the positioning protrusion 3152a moves into the positioning groove 3152b.

See FIG. 9 . The bobbin seal clamping mechanism 32 has a first moving module 321 , a second moving module 322 and a clamping module 323 . The first moving module 321 includes a first movable jaw drive source 3211 capable of single-stage moving travel and a first jaw transmission member 3212 connected to the first movable jaw drive source 3211 . ) has; The first movable jaw drive source 3211 and the first jaw transmission member 3212 are generally connected with an avoidance unit 324 ; The avoidance unit 324 causes both the first movable jaw drive source 3211 and the first jaw transmission member 3212 to move relative to the second movement module 322 . By doing so, when the first movable jaw drive source 3211 drives the first jaw transmission member 3212 to move, both the first movable jaw drive source 3211 and the first jaw transmission member 3212 are It can move relative to the second movement module 322 via the avoidance unit 324 .

In this embodiment, the avoiding unit 324 includes a swinging plate 3241 assembled to the first movable jaw driving source 3211 , and an assembling plate assembled to the second moving module 322 . 3242 and a roller 3243 assembled to the fixed frame 14 , so that the swing plate 3241 can swing relative to the assembly plate 3242 . The assembly plate 3242 is concave to form a low-centered curved guide rail 3242a, and the curved guide rail 3242a is a guide connected to the first set transmission member 3212. contact a guide wheel 3244; A holding member 3245 is disposed between the swing plate 3241 and the assembly plate 3242 . The swing plate 3241 and the assembly plate 3242 collectively press the holding member 3245 to generate a holding force 3245a acting on the swing plate 3241; Thus, the swing plate 3241 can swing relative to the assembly plate 3242 by the holding force 3245a, which causes the guide wheel 3244 to move toward the curved guide rail 3242a, which 3244 continues to contact the curved guide rail 3242a through the retaining force 3245a of the retaining member 3245 .

As shown in the figure, the second moving module 322 is connected to a second movable jaw driving source 3221 and a second movable jaw driving source 3221 capable of two-stages moving travel. and a second transmission member 3222 . The second movable jaw driving source 3221 is assembled to the fixed frame 14 of the sewing machine body 10 , and the second movable jaw transmission member 3222 is connected to the assembly plate 3242 of the second movable module 322 . . By doing so, when the second movable jaw driving source 3221 drives the second jaw transmission member 3222 to move, the first moving module 321 as a whole is moved by the second jaw transmission member 3222 . is driven The clamp module 323 also has a movable clamp 3231 pivotally coupled to the first jaw transmission member 3212 and a fixed clamp 3232 fixed to the first jaw transmission member 3212 . The movable clamp 3231 is selectively moved closer to the end of the fixed clamp 3232 or the fixed clamp 3232 by a clamp drive source 3233 mounted on the first set transmission member 3212 . is driven away from the end of the (shown in Figure 16a).

9, the end of the movable clamp 3231 has a clamping groove 3231a, and the end of the fixed clamp 3232 is a clamping block having a smaller volume than the clamping groove 3231a ( 3232a). As shown in the figure, when the clamp drive source 3233 drives the movable clamp 3231 to swing, the movable clamp 3231 moves closer to the fixed clamp 3232, and thus the clamp block 3232a ) moves into the clamping groove 3231a, and the clamping block 3232a and the clamping groove 3231a are in close contact. In the present embodiment, the movable clamp 3231 has a stop pin 3231b provided in the middle of the clamping groove 3231a, and the clamping block 3232a of the fixed clamp 3232 has a pin hole 3232b. ) is concave to form. When the clamping block 3232a and the clamping groove 3231a are in close contact, the stop pin 3231b will enter the pin hole 3232b.

See Figures 5 and 10. The actual release mechanism 33 has a release lever 331 and a release drive source 332 . The release lever 331 has a pivot connection 3311 pivotally coupled to the stationary frame 14, and the two ends of the pivot connection 3311 are each a pushing portion spaced apart from the connection plate 3112a. An action portion 3313 connected to a pushing portion 3312 and an emission driving source 332 is formed. A clamping space 3314 (shown in FIG. 7 ) is disposed between the edge portion 3112c of the blade 3112b and the connecting plate 3112a. The ejection drive source 332 can generate power to drive the actuation portion 3313 to move, which causes the ejection lever 331 to swing relative to the pivot connection 3311 ; Accordingly, the pushing portion 3312 can optionally be moved closer to the back of the connecting plate 3112a or farther from the back of the connecting plate 3112a, and the pushing portion 3312 is the connecting portion 3112d of the blade 3112b. Push the lower end. Accordingly, the edge portion 3112c moves away from the connecting plate 3112a to allow the clamping space 3314 to exhibit an open state into which the bobbin seal 60 enters. 5 and 11 , the bobbin yarn control mechanism 34 is positioned between the bobbin module operating mechanism 31 and the yarn gripper 15 , and operates the adjustment member 341 and the adjustment drive source 342 . have The adjustment member 341 has a pivoting shaft 3411 pivotally connected to the stationary frame 14, one end of the pivot shaft 3411 having an adjustment plate 3412 and a connecting post ( 3413); The through hole 3412a is formed to pass through a partial region of the adjustment plate 3412 , the connection post 3413 is connected to the adjustment drive source 342 , and the adjustment drive source 342 pivots the adjustment member 341 . Power may be generated to drive it to swing relative to shaft 3411 .

See FIG. 12 . The residual bobbin thread removing device 40 is located on one side of the bobbin module rotating assembly 25 of the bobbin module, and has a movable mechanism 41 , a thread cutting mechanism 42 and a suction mechanism 43 . The movable mechanism 41 has a movable drive source 411 assembled to the stationary frame 14 and a movable arm 412 pivotally connected to the stationary frame 14 . A movable drive source is coupled to the movable arm 412 and can drive the movable arm 412 to move and swing. The thread cutting mechanism 42 has a cut drive source 421 assembled to a movable arm 412 and a cutter 422 that can be driven by the cut drive source 421 . The cut drive source 421 is assembled with the cut transmission member 423 , the cut drive source 421 can drive the cutter 422 to rotate through the cut transmission member 423 , and the cutter 422 is It is located above the bobbin module operating mechanism 31 . As shown in the figure, the suction mechanism 43 is coupled to the movable arm 412 and has a suction port 431 , the suction mechanism 43 having a suction airflow A (shown in FIG. 15B ). ) can be created.

See FIG. 13 . The bobbin 51 of the bobbin module 50 is mounted on the first transmission member 3112 of the first operation module 311 , and the alignment mechanism 44 is disposed between the bobbin 51 and the first transmission member 3112 . is placed on The alignment mechanism 44 may restrict the through space 514 of the bobbin 51 to be directly above the bobbin 51 when the bobbin 51 is assembled to the first transfer member 3112 , which is the through space. 514 brings it closer to the cutter 422 of the thread cutting mechanism 42 . As shown in the figure, the alignment mechanism 44 has a guiding module 441 and a positioning module 442 . The guiding module 441 is composed of two magnets 4411 . The positioning module 442 is composed of a bump 4421 and a positioning groove 4422, which can be engaged with each other. As shown in the drawing, the two magnets 4411 are assembled to the bobbin 51 and the first transmission member 3112, respectively. In addition, the bump 4421 is formed on the first transmission member 3112 , and the positioning groove 4422 is formed on the bobbin 51 . When the bobbin 51 is assembled to the first transmission member 3112 , the bobbin 51 may be in a freely rotatable state. Then, the first transmission member 3112 drives the bobbin 51 to rotate, so that the two magnets 4411 are connected to each other to shorten the relative distance between the bobbin 51 and the first transmission member 3112 . magnetically attracted to and the bump 4421 further engages the positioning groove 4422 to limit the relative angular position between the bobbin 51 and the first transfer member 3112; Therefore, the bobbin 51 cannot rotate with respect to the eleventh transmission member 3112, and when the first transmission member 3112 stops rotating and is positioned at an angle, the through space 514 corresponds to the cutter 422. It may be located directly above the bobbin (51).

See FIG. 14 . In a specific application, the rotary hook 12 of the sewing machine body 10 and the bobbin module operating mechanism 31 of the bobbin thread introducing device 30 are each assembled with the bobbin module 50 wound with the bobbin thread 60; Accordingly, the bobbin module 50 of the rotary hook 12 is set as the first bobbin module 501 , and the bobbin module 50 assembled in the bobbin module operation mechanism 31 is set as the second bobbin module 502 . do; Further, the bobbin thread 60, disposed on the sewing machine body 10, is assembled to the thread gripper 15 of the sewing machine body 10; The bobbin thread 60 disposed in the sewing machine body 10 passes through the through hole 3412a of the bobbin thread control mechanism 34, so that the partial section of the bobbin thread 60 disposed in the sewing machine body 10 is It may be located inside the clamping space 3314 of the thread release mechanism 33, whereby the edge portion 3112c of the blade 3112b and the connecting plate 3112a of the first transmission member 3112 are connected to the sewing machine body 10 ) to clamp the bobbin thread 60 disposed in the batch.

See Figure 14b. When the sewing machine body 10 performs a sewing operation so that the amount of the lower thread 60 of the first bobbin module 501 is almost dropped, the moving driving source 211 of the bobbin module moving assembly 21 generates moving power. ; Accordingly, the bobbin module moving assembly 21 moves closer to the rotary hook 12 as a whole along the transfer rod 212, and the movable frame 22 moves the first and second set assemblies 23 and 24, respectively. It drives so as to approach the rotary hook 12 of the sewing machine body 10 and the bobbin module operation mechanism 31 of the bobbin thread introducing device 30 .

See Figures 14c and 14d. When the first and second set assemblies 23 and 24 approach the rotary hook 12 of the sewing machine body 10 and the bobbin module operation mechanism 31 of the bobbin thread introducing device 30, respectively, the first assembly The first fixing jaw 232 of 23 is in contact with the bobbin case 52 of the first bobbin module 501, while the second fixing jaw 242 of the second assembly 24 is the second bobbin module It is in contact with the bobbin case 52 of 502 . Then, the first jaw driver 234 drives the first movable jaw 233 to swing, so that the first clamping portion 233a of the first movable jaw 233 is attached to the first fixed jaw 232 . Moving closer, the first clamping part 233a is fixed to the latch clip 3151b disposed on the first bobbin module 501 . By doing so, the first movable jaw 233 and the first fixed jaw 232 collectively clamp the first bobbin module 501; On the other hand, the second jaw driver 244 drives the second movable jaw 243 to swing, so that the second clamping portion 243a of the second movable jaw 243 is attached to the second fixed jaw 242. Moving closer, the second clamping portion 243a is fixed to the latch clip 3151b disposed on the second bobbin module 502 . By doing this, the second movable jaw 243 and the second fixed jaw 242 clamp the second bobbin module 502 collectively.

See Figures 14E and 14F. When the first article assembly 23 and the second article assembly 24 clamp the first bobbin module 501 and the second bobbin module 502, respectively, the movement driving source 211 of the bobbin module moving assembly 21 ) generates movement power; Therefore, the bobbin module moving assembly 21 moves away from the rotary hook 12 along the transfer rod 212 as a whole, and the first assembly 23 moves the first bobbin module 501 to the sewing machine body ( 10) drive to move away from the rotary hook 12 of the, on the other hand, the second assembly 24, the second bobbin module 502, the bobbin module operating mechanism 31 of the bobbin thread introducing device 30 drive it to move away from it. By doing so, the first jaw assembly 23 can separate the first bobbin module 501 from the rotary hook 12 through the bobbin module moving assembly 21, and the second jaw assembly 24 can also The bobbin module 502 is separated from the bobbin module operating mechanism 31 via the bobbin module moving assembly 21 .

The rotational drive source 251 of the bobbin module rotation assembly 25 can then generate rotational power, thus the first transmission gear 252a of the transmission module 252 and the second transmission of the transmission module 252 . The gear 252b drives the transmission rod 212 of the bobbin module moving assembly 21 to rotate, which causes the transmission rod 212 to rotate the movable frame 22 clockwise in the direction of the arrow in the drawing, Accordingly, the second bobbin module 502 is positioned directly in front of the rotary hook 12 .

See Figures 14G and 14H. Again, the moving driving source 211 of the bobbin module moving assembly 21 generates moving power, so that the moving driving source 211 transmits the moving frame 22 along the transfer rod 212 to the sewing machine body 10 . drive to approach the rotary hook 12 of the second bobbin module 502 is mounted on the rotary hook 12; And, the second jaw driver 244 of the second jaw assembly 24 drives the second clamping portion 243a of the second movable jaw 243 away from the latch clip 3151b, and thus, The second bobbin module 502 is actually assembled to the rotary hook 12 ; Now, the first jaw assembly 23 still clamps the first bobbin module 501 .

See Figures 14i, 14j and 14k. The second bobbin module 502 is assembled to the rotary hook 12, and the movable frame 22 of the bobbin changing device 20 is formed by the bobbin module moving assembly 21 and the bobbin module rotating assembly 25, driven to bring the jaw assembly 23 closer to the bobbin module operating mechanism 31 of the bobbin thread introducing device 30, which causes the first bobbin module 501 to be mounted to the bobbin module operating mechanism 31; When the first bobbin module 501 is mounted on the bobbin module operation mechanism 31 , the third transmission member 3132 of the third operation module 313 engages the bobbin shaft 522 of the first bobbin module 501 . The positioning protrusion 3152a of the limiting assembly 315 moves through the limiting assembly 315 in order to pass, thus limiting the rotation of the bobbin case 52 of the first bobbin module 501 about the operating axis L. ) into the positioning groove 3152b.

As shown in the figure, when the positioning protrusions 3152A of the restraint assembly 315 fit into the positioning grooves 3152B of the restraint assembly 315, the first jaw driver 234 of the first jaw assembly 23 ) drives the first clamping portion 233A of the first movable jaw 233 to move away from the latch clip 3151B disposed in the first bobbin module 501; The latch clip 3151b disposed in the first bobbin module 501 holds the latch 3151c in order to limit the bobbin case 52 of the second bobbin module 502 from having movement along the axis of motion L. It rebounds to snap into the annular groove 3151A of the restriction assembly 315 .

Then, the movement driving source 211 of the bobbin module movement assembly 21 generates movement power to drive the movable frame 22 to move away from the rotary hook 12, and now, the first assembly assembly Article 23 and Article 2 assembly 24 do not hold bobbin module 501 and second module 502, respectively, which means that Article 1 assembly 23 and Article 2 assembly 24 are both bobbins. Waiting for the next operation to keep the module 50 .

See FIG. 14L. When the first bobbin module 501 is mounted on the bobbin module operating mechanism 31 , the bobbin 51 of the first bobbin module 501 is close to the connecting plate 3112a of the first transmission member 312 . At this time, the bobbin 51 may be in a freely rotatable state. And, the first transmission member 3112 drives the bobbin 51 to rotate in the clockwise direction, so that the bobbin 51 of the first bobbin module 501 rotates about the operation axis L. To allow, the guiding module 441 of the two magnets 4411 is magnetically attracted to each other; Also, to limit the relative angular position between the bobbin 51 and the first transmission member 3112 of the first bobbin module 501 , the bump 4421 of the alignment mechanism 44 is positioned in the positioning groove of the alignment mechanism 44 . (4422) engages; Further, when the first transmission member 3112 rotates several times and then stops at the angular position, the through space 514 of the first bobbin module 501 can be positioned directly above the spool member 511 ; In addition, when the first transmission member 3112 rotates, the bobbin 51 of the first bobbin module 50 may rotate through the first transmission member 3112, and the housing 521 and the clamping elastic piece ( Not only the partial bobbin thread 60 between 528 , but also the partial bobbin thread 60 exposed outside the thread guiding hole 526 can be wound back into the bobbin case 52 by the rotating bobbin 51 , which for subsequent thread cutting operations. In this embodiment, the bobbin 51 has two through spaces 514; The two through spaces 514 are spaced apart by 180°; Further, both the alignment mechanism 44 and the through space 514 are formed 180° symmetrically. Accordingly, the boburn 51 has two angles for positioning.

See Figure 15a. When neither the first jaw assembly 23 nor the second jaw assembly 24 clamp the bobbin module 50, the remaining bobbin thread 60 in the first bobbin module 501 begins to be removed. First, the third driving source 3131 of the third operation module 313 drives the third transmission member 3132 of the third operation module 313 to move along the operation axis L, which is a synchronization module Synchronous protruding pillars 3142 of 314 allow movement toward the end portion of synchronization groove 3141; Therefore, the moving second transmission member 3132 can drive the bobbin case 52 of the first bobbin module 501 to be separated from the bobbin 51 of the first bobbin module 501 in the axial direction, The bobbin case 52 of the first bobbin module 501 and the bobbin 51 of the first bobbin module 501 are separated from each other to represent a separated state S1.

See Figure 15b. Then, the cutting driving source 421 of the thread cutting mechanism 42 drives the cutter 422 of the thread cutting mechanism 42 to rotate, and the suction mechanism 43 is operated to generate the suction airflow A to start And, the movable driving source 411 of the movable mechanism 41 drives the movable arm 412 of the movable mechanism 41 to swing, and the cutting drive source 421 , the cutter 422 and the suction mechanism 43 . This simultaneously causes it to swing downward, thereby causing the rotating cutter 422 to move to the cutting position C to cut the remaining bobbin thread 60 inside the winding space 513 . When the bobbin thread 60 inside the winding space 513 is cut by the cutter 422 , the suction port 431 of the suction mechanism 43 will be located on one side of the bobbin 51 , which is the suction The suction airflow A of the mechanism 43 causes the bobbin thread 60 cut by the cutter 422 to be removed. As shown in the figure, since the alignment mechanism 44 can limit the through space 514 of the first bobbin module 501 just above the spool member 511 , the cutter 422 moves to the cutting position C. When at , the through space 514 may be aligned with the cutter 422 positioned at the cutting position C via the alignment mechanism 44 ; Thus, the cutter 422 can not only enter the through space 514 to ensure that the cutter 422 can truly cut the bobbin thread 60 , but also can certainly obstruct the spool member 511 . none. And, the movable drive source 411 of the movable mechanism 41 drives the movable arm 412 of the movable mechanism 41 to swing upward, so that the cutting drive source 421, the cutter 422 and the suction The three mechanisms 43 are remote from the bobbin 51 ; In order to enhance the effect of sucking the remaining bobbin thread 60 by the suction mechanism 43 when the cutter 422 leaves the through space 514 of the bobbin 51, the first operation module 311 1 the transmission member 3112 can drive the bobbin 51 to rotate; Accordingly, the bobbin 51 of the first bobbin module 501 shows an initial state S2 that is not wound with the bobbin thread 60 , that is, the operation of removing the bobbin thread 60 is completed. .

See Figure 15c. The movable arm 412 of the suction mechanism 43 assembled to the movable mechanism 41 is only for convenience of description, that is, the suction mechanism 43 can be assembled to the fixed frame 14 of the sewing machine body 10 . have; Accordingly, when the movable arm 412 swings, the suction mechanism 43 does not swing as the movable arm 412 . As shown in the figure, the suction port 431 of the suction mechanism 43 is located below the bobbin 51, and the appearance of the suction port 431 represents a funnel, whereby the cutter 422 is When in the cutting position C to cut the bobbin thread 60 , the suction mechanism 43 can receive the bobbin thread 60 that naturally falls off after being cut by the cutter 422 , and thus the bobbin The thread 60 is removed from the bobbin 51 by the suction airflow A.

See Figure 15d. In a preferred embodiment, the cut transmission member 423 of the thread cutting mechanism 42 is connected to a source of pneumatic pressure (not shown in the figure) capable of generating an airflow, and the cut transmission member 423 includes a cutter 422 . ) A plurality of air blowing holes (air blowing holes) (423a) close to are provided. Accordingly, when the cutter 422 is in the cutting position C to cut the bobbin thread 60 , in order to prevent the cut bobbin thread 60 from being wound around the cut transmission member 423 , the pneumatic source Temporary air creates a blowing air flow (B) flowing out of the air blowing holes (423a).

Referring to FIG. 16A , after the bobbin thread 60 is removed, the operation of winding the bobbin thread 60 is started. First, the first drive source 3111 of the first operation module 311 generates rotational power to drive the first drive belt pulley 3113a of the first interlocking module 3113 to rotate, which is the first The first belt 3113c of the interlocking module 3113 rotates the first transmission member 3112 about the operation axis L through the first driven belt pulley 3113b of the first interlocking module 3113. drive, and thus, the bobbin thread 60 inside the clamping space 3314 starts to rotate together with the first transmission member 3112, so that the bobbin 51 of the first bobbin module 501 moves the bobbin thread. It rotates synchronously to bring 60 into the winding space 513 of the bobbin 51 .

In the initial stage, the bobbin 51 of the first bobbin module 501 is wound with a bobbin thread 60 . Since the outer diameter of the first winding portion 511a of the first bobbin module 501 is smaller than the outer diameter of the second winding portion 511b of the first bobbin module 501 , the bobbin thread 60 is the first bobbin module To ensure that the through space 514 of the 501 is covered, the bobbin thread 60 is first wound around the first winding 511a of the bobbin 51 ; Accordingly, the remaining bobbin thread 60 on the bobbin 51 of the first bobbin module 51 after the sewing operation also remains in the first winding portion 511a, whereby the thread cutting mechanism 42 at the cutting position C ) of the cutter 422 can truly cut the bobbin thread 60 . In a preferred embodiment, in order to further ensure that the bobbin yarn 60 is first wound on the first winding portion 511a in the initial stage of the winding operation, the adjustable drive source 342 of the bobbin yarn control mechanism 34 is Drive the adjustment member 341 of the bobbin yarn control mechanism 34 to swing, which causes the through hole 3412a of the adjustment member 341 to further restrict the bobbin yarn 60 to the connecting plate 3112a. When the bobbin thread 60 is wound on the first winding portion 511a a certain number of times (eg, 10 or 20 turns), the adjustment drive source 342 passes the adjustment member 341 through the through hole 3412a. The bobbin thread 60 is driven so as not to restrict the movement, so that the bobbin thread 60 is uniformly wound around the spool member 511 of the bobbin 51 . Further, when the bobbin yarn 60 is wound around the first winding portion 511a a certain number of times (eg, 10 or 20 times), the discharge driving source 332 of the yarn releasing mechanism 33 also causes the yarn releasing mechanism Drives the ejection lever 331 of 33 to swing, and thus the pushing portion 3312 of the ejection lever 331 ejects the bobbin seal 60 of the blade 3112b (shown in Fig. 16f). Pushing the lower end of the connecting portion 3112d, which causes the end of the bobbin thread 60 inside the clamping space 3314 to loosen and at the same time to be wound into the winding space 513. Immediately, the ejection driving source 332 drives the pushing portion 3312 to move away from the connecting plate 3112a, so that the blade 3112b connects the edge portion 3112c to the connecting plate through its own elastic force. to come into contact with (3112a); Next, when the bobbin 51 of the first bobbin module 501 is wound with the bobbin thread 60 up to a preset number of times, the inside of the winding space 513 of the first bobbin module 501 is the bobbin thread 60 is completely wound, and at this time, the first driving source 3111 of the first operation module 311 stops the rotation.

See Figure 16b. After stopping the winding of the bobbin thread 60, since the relative positional relationship between the bobbin thread 60 and the clamp module 323 cannot be determined, the regulating drive source 342 of the bobbin thread control mechanism 34 is It is necessary to drive the adjustment member 341 of the yarn control mechanism 34 to swing relative to the pivot shaft 3411, which means that the adjustment plate 3412 of the adjustment member 341 engages the yarn gripper 15 and the bobbin ( 51) to come into contact with the bobbin thread 60 positioned between the bobbin thread 60 positioned between the thread gripper 15 and the bobbin 51, and thus the through hole 3412a of the adjustment plate 3412 is positioned between the thread gripper 15 and the bobbin 51. is limited to be close to the clamp module 323 . This in turn ensures that the clamp module 323 clamps the bobbin thread 60 positioned between the thread gripper 15 and the bobbin 51 . To achieve the above-described effect, another implementation procedure is to drive the adjustment drive source 342 to swing the adjustment member 341 before stopping the winding of the bobbin thread 60 , which is the adjustment plate 3412 . is brought into contact with the bobbin thread 60 between the thread gripper 15 and the bobbin 51; Accordingly, the bobbin thread 60 positioned between the thread gripper 15 and the bobbin 51 is limited to be close to the clamp module 323, which means that the bobbin thread 60 finally wound around the bobbin 51 is clamped. to be on the path of movement of the module 323 .

See Fig. 16c. The first movable jaw driving source 3211 of the first moving module 321 drives the first jaw transmitting member 3212 of the first moving module 321 to extend outward, and the bobbin thread clamping mechanism 32 The clamp module 323 of the clamp module 323 is moved along a first path D1 (shown in FIG. 16D ) intersecting the motion axis L by the first set transmission member 3212 in a first ready position P1 ( FIG. 16D ). 16a) to the clamping position P2, where the bobbin thread 60 between the bobbin 51 and the thread gripper 15 is positioned between the movable clamp 3231 and the fixed clamp 3232. make it In this embodiment, during the movement of the clamp module 323 from the first ready position P1 to the clamping position P2 , the guide wheel 3244 of the avoiding unit 324 exerts a holding force 3245a of the holding member 3245 . ) in continuous contact with the curved guide rail 3242a of the assembly plate 3242, and thus, the guide wheel 3244 from one end of the curved guide rail 3242a to the other of the curved guide rail 3242a. When moving to the end, the swing plate 3241 of the avoiding unit 324 drives to swing the first moving module 321 and the clamp module 323 in a counterclockwise path, which causes the clamp module 323 to In order to avoid the bobbin 51 of the first bobbin module 501, three parts (the first moving jaw drive source 3211, the first jaw transmission member 3212 and the clamp module 323 and the first bobbin module ( 501) further change the relative position between the 501. Through this, when moving to the clamping position P2 along the first path D1, the clamp module 323 can be moved through the avoiding unit 324 to the first bobbin module 501 ) of the bobbin 51. When the clamp module 323 of the bobbin thread clamping mechanism 32 is in the clamping position P2, the stop pin 3231b of the movable clamp 3231 It is possible to contact the bobbin thread 60 between the thread gripper 15. Through this, when the bobbin thread 60 is in a loose state, the stop pin 3231b is connected to the movable clamp 3231 and the fixed clamp 3232. ) can limit the local length of the bobbin thread 60 , whereby the relative positional relationship between the bobbin thread 60 and the clamp module 323 when the clamp module 323 clamps the bobbin thread 60 . Then, the clamp driving source 3233 of the clamp module 323 drives the movable clamp 3231 of the clamp module 323 to swing, which means that the movable clamp 3231 is the clamp module 323 . to move closer to the fixing clamp (3232), and At a position near the adjustment member 341 , a movable clamp 3231 and a fixed clamp 3232 clamp the bobbin thread 60 positioned between the bobbin 51 and the thread gripper 15 . At this time, the clamping block 3232a of the fixing clamp 3231 moves into the clamping groove 3231a, so that the clamping groove 3231a and the clamping block 3232a are in close contact, which means that the bobbin thread 60 is In order to prevent separation from the clamping module 323, the clamping groove 3231a and the clamping block 3232a clamp the bobbin seal 60, and the clamping groove 3231a and the clamping block 3232a together the bobbin seal Let the clamping local length of (60). Here, the bobbin thread 60 is set as the source bobbin thread 62 assembled to the thread gripper 15 as well as the bobbin thread 61 wound between the bobbin 51 and the clamp module 323 . is divided into the rest of the

See Figures 16E and 16F. The first movable jaw driving source 3211 of the first moving module 321 drives the first jaw transmitting member 3212 of the first moving module 321 to move backward, and the bobbin thread clamping mechanism 32 of the clamp module 323 is driven to return from the clamping position P2 to the first ready position P1 along the first path D1, which means that the source bobbin thread 62 is the first bobbin module 501 Let it pass under the bobbin (51). At this time, the ejection driving source 332 of the yarn ejection mechanism 33 drives the ejection lever 331 of the yarn ejection mechanism 33 to swing, which means that the pushing portion 3312 of the ejection lever 331 is the blade. The edge portion 3112c of the blade 3112b is connected to push the lower end of the connecting portion 3112d of the blade 3112b, thereby allowing the clamping space 3314 to exhibit an open state into which the bobbin seal 60 enters. away from plate 3112a. Then, the first driving source 3111 of the first operation module 311 drives the first transmission member 3112 to rotate clockwise through the first interlocking module 3113 , which is the source bobbin thread 62 . ) to pass through the inside of the clamping space 3314 . And, the ejection drive source 332 drives the ejection lever 331 to swing, which causes the pushing portion 3312 of the ejection lever 331 to move away from the lower end of the connecting portion 3112d of the blade 3112b. ; Accordingly, in order to wait for the next operation to wind the bobbin thread 60, the blade 3112b has its own elastic force, so that the edge portion 3112c of the blade 3112b and the connecting plate 3112a are connected to the source bobbin thread 62 together. ) (shown in Fig. 16f) to be clamped. Then, the second movable jaw driving source 3221 of the second moving module 322 drives the second jaw transmitting member 3222 of the clamp module 323 to make a first stage moving travel, and thus, 1 The moving module 323 and the clamp module 323 are both driven to move by the Article 2 transmission member 3222, whereby the clamp module 323 is moved from the first ready position P1 to the first path moving to the first guiding position P3 along the second path D2 intersecting with D1; When the clamp module 323 is in the first guiding position P3, the source bobbin seal 62 will contact the edge portion 3112c of the blade 3112b. Subsequently, as shown in FIGS. 16G and 16H , the first driving source 3111 of the first moving module 311 moves the first transmission member 3112 through the first interlocking module 3113 to the operating axis ( L) is driven to rotate counterclockwise, which causes the blade 3112b to be driven to cut the source bobbin thread 62 by the first transmission member 3112 . At this time, the end of the source bobbin thread 62 is clamped by the blade 3112b, while the end of the wound bobbin thread 61 is clamped by the clamp module 323 . 16A to 16H , the fact that the bobbin case 52 is separated from the bobbin 51 in the axial direction is for convenience of description. In fact, the relative distance between the bobbin case 52 and the bobbin 51 should be represented substantially as the separated state S1 in FIG. 15A . In addition, in Fig. 16G, in order to clearly show the angular state of the blade 3112b, the bobbin 51 is moved out of the connecting plate 3112a.

16A to 16E, in order to prevent the clamp module 323 from moving along the first path D1, the clamp module 323 connects the connecting plate 3112a and the blade 3112b. will interfere; The first operation module 311 can drive the connecting plate 3112a and the blade 3112b to rotate, which causes the blade 3112b to rotate at an angle to avoid the clamp module 323, but as shown in the figure angle is not limited.

See Figure 17a. After the cutting of the bobbin thread 60 is completed, the wound bobbin thread 61 starts to be installed on the bobbin case 52 of the first bobbin module 501 . First, the third driving source 3131 of the third operation module 313 drives the third interlocking module 3133 to move away from the third transmitting member 3132; The restoring force 3134a of the resetting member 3134 acts on the pressing block 3132a, which causes the third transmission member 3132 to move toward the third drive source 3131, thereby causing the moving third the transmission member 3132 allows the bobbin case 52 of the first bobbin module 501 to be assembled to the bobbin 51 of the first bobbin module 501; Accordingly, the bobbin case 52 of the first bobbin module 501 and the bobbin 51 of the first bobbin module 501 are converted from a separated state ( S1 ) to an assembled state ( S3 ) in which they are assembled to each other. At this time, the wound bobbin thread 61 is in contact with the open end 524 of the bobbin case 52, and the wound bobbin thread 61 is in a tensioned state.

See Figure 17b. When the bobbin thread 60 with the bobbin is in contact with the open end 524 of the bobbin case 52 , the second driving source 3121 of the second operation module 312 moves to the second of the second interlocking module 3123 . Generates rotational power to drive the drive belt pulley 3123a to rotate, which causes the second transmission member 3122 to move the second transmission member 3122 to the second driven belt pulley ( 3123b) to drive it to rotate about the operating axis L; When the second transmission member 3122 rotates, the synchronization protruding pillar 3142 of the synchronization module 314 cannot move due to the limitation of the synchronization groove 3141, and thus the second transmission member 3122 is synchronized Through the module 314, the third operation module 313 is driven to rotate, which causes the bobbin case 52 of the first bobbin module 501 to rotate synchronously. As shown in the figure, the second driving source 3121 first drives the bobbin case 52 of the first bobbin module 501 to rotate clockwise through the second transmission member 3122, and then 2 the driving source 3121 drives the bobbin case 52 of the first bobbin module 501 to rotate counterclockwise; Accordingly, the bobbin thread 61 on which the rotating bobbin case 52 is wound can be guided into the thread guiding slot 527 of the bobbin case 52, which means that the local length of the bobbin thread 61 wound around the bobbin It is positioned between the case 52 and the clamping elastic piece 528 of the bobbin case 52 .

See Fig. 17c. Next, the second movable jaw drive source 3221 of the second movement module 322 drives the second jaw transmission member 3222 of the clamp module 323 to make a second stage movement travel, which Both the moving module 321 and the clamping module 323 are driven by the second transmitting member 3222 to move away from the connecting plate 3112a, so that the clamping module 323 is connected to the second path D2 ) moves from the first guiding position P3 to the second preparation position P4 along the third path D3 parallel to the . As shown in FIG. 17D , during the moving process of the clamp module 323 toward the second ready position P4 , the first set transmitting member 3212 of the first moving module 321 is moved by the avoiding unit 324 . It comes into contact with the roller 3243, which causes the swing plate 3241 of the avoiding unit 324 to swing, which causes the guide wheel 3244 of the avoiding unit 34 to separate from the curved guide rail 3242A. Thus, the bobbin thread clamping mechanism 32 pulls the wound bobbin thread 61, which causes the wound bobbin thread 61 to be introduced into the guiding opening 528a of the clamping elastic piece 528, thereby clamping The bobbin thread 61 on which the elastic piece 528 is wound may be guided from the thread guiding slot 527 to the thread guiding hole 526 .

See Figure 17e. When the clamp module 323 is positioned in the second ready position P4, the first movable jaw driving source 3211 of the first moving module 321 is the first movable jaw driving member 321 of the first moving module 321 ( drive again to extend outwardly 3212 , so that the first article transfer member 3212 moves the clamp module 323 to a second ready position along a fourth path D4 parallel to the first path D1 . drive to move from (P4) to the second guiding position (P5); During the moving process of the clamp module 323 toward the second guiding position P5, the wound bobbin thread 61 first contacts the hook arm 529 of the bobbin case 52, and then, the wound bobbin The thread 61 pushes the elastic arm 530a of the thread blocking piece 530, which causes the elastic arm 530a to be deformed, and thus the wound bobbin thread 61 is inserted into the thread hole ( 529a). Thus, the operation of mounting the bobbin thread 61 wound with the bobbin case 52 is completed; The wound bobbin thread 61 is located inside the thread hole 529a, and the elastic arm 530a overlaps the thread hole 529a because it is not pushed by the wound bobbin thread 61, which is the elastic arm 530a. ) to prevent the wound bobbin thread 61 blocked from being separated from the thread hole 519a.

See Fig. 17f. The wound bobbin thread 61 is guided into the thread hole 529a of the hook arm 529 , and the clamp driving source 3233 of the clamp module 323 holds the movable clamp 3231 of the clamp module 323 . drive to swing; Accordingly, the movable clamp 3231 is moved away from the fixed clamp 3232 of the clamp module 323 , whereby the clamp module 323 releases the end of the bobbin thread 61 that is wound. Finally, the clamp module 323 moves back to the first ready position P1 from the second guiding position P5 through the first moving module 321 and the second moving module 322, which is the clamp module Wait 323 to mount bobbin seal 60 to bobbin case 52 .

See FIG. 18 . In the second preferred embodiment, the difference from the first preferred embodiment is the assembly sequence between the first operation module 311 , the second operation module 312 , the third operation module 313 and the synchronization module 314 . to be. As shown in the figure, the second transmission member 3122 of the second operation module 312 is movably disposed through the first transmission member 3112 of the first operation module 311, and the second operation The second interlocking module 3123 of the module 312 is configured as a single hollow shaft, and the third transmission member 3132 is movably assembled on the outer periphery of the second interlocking module 3132 and is synchronized with the synchronization module 314 . assembled to the second transmission member 3122 via the protruding pillar 3142; The first transmission member 3112 and the third transmission member 3132 are respectively located on opposite sides of the second transmission member 3122 . In addition, the third interlocking module 3133 of the second operation module 313 includes an interlocking rack 3133a capable of driving the axial displacement of the second transmission member 3132 and a third driving source 3131 . ) is provided with an assembled interlocking gear (interlocking gear) (3133b); The interlocking rack 3133a meshes with the interlocking gear 3133b. The synchronization groove 3141 of the synchronization module 314 is formed in the second interlocking module 3123, which makes the synchronization groove 3141 in an elongated form, whereby the synchronization protrusion pillar 3142 is formed in the first 3 The transmission member 3132, the second interlocking module 3123, and the second transmission member 3122 are disposed to pass through at the same time.

In the present embodiment, when the second driving source 3121 of the second operation module 312 generates rotational power, the second driving source 3121 moves the second transmission member 3122 to the first transmission member ( 3112) is driven to rotate. At this time, the synchronization protruding pillar 3142 of the synchronization module 314 will not be affected by the first transmission member 3112 to rotate, and the synchronization groove 3141 of the synchronization module 314 will be rotated by the second transmission member It rotates synchronously with (3122). In addition, the third driving source 3131 of the third operation module 313 generates rotational power, and the interlocking gear 3133b of the third interlocking module 3133 is the interlocking rack 3133a of the third interlocking module 3133 . ) to move; Accordingly, the third transmission member 3132 moves along the motion axis L. Further, when the third transmission member 3132 moves, the synchronization protruding pillar 3142 of the synchronization module 314 moves along the synchronization groove 3141 of the synchronization module 314, which is the third transmission member 3132 causes the entire second transmission member 3122 to move axially through the synchronization module 314 .

See FIG. 19 . In the third preferred embodiment, the difference from the second preferred embodiment is that the bobbin module operating mechanism 31 does not have the synchronization module 314 and the third transmitting member 3132 of the third operating module 313 . will be; The second drive source 3121 configured as a plate member and assembled to the second operation module 312 prevents the third transmission member 3132 from being coaxially disposed on the operation axis L; When the third driving source 3131 of the third operation module 313 drives the third transmission member 3132 to move along the axial direction of the operation axis L, the entire second operation module 312 ( The second driving source 3121, the second transmission member 3122, and the second interlocking module 3123) simultaneously move along the operation axis L, so that the bobbin case 52 moves the bobbin 51 ) to separate from it. In this embodiment, the third transmission member 3132 may be directly connected to the third driving source 3131 . However, the third transmission member 3132 may be connected to the third driving source 3131 through the third interlocking module 3133 .

However, the assembly of the third transmission member 3132 to the second driving source 3121 is for convenience of explanation, that is, the third transmission member 3132 is the first driving source ( 3111 , whereby the entire first operation module 311 (including the first driving source 3111 , the first transmission member 3112 , and the first interlocking module 3113 ) is configured to include the third When the transmission member 3132 moves along the motion axis L through the third drive source 3131 , it may simultaneously move along the motion axis L, which causes the bobbin 51 to separate from the bobbin case 52 . move as much as possible.

Also, in this embodiment, before the bobbin thread 60 is wound on the bobbin 51, the clamp module 323 of the bobbin thread clamping mechanism 32 can temporarily clamp the source bobbin thread 62, Then, the ejection driving source 332 of the yarn ejection mechanism 33 drives the ejection lever 331 of the yarn ejection mechanism 33 to swing, which means that the pushing portion 3312 of the ejection lever 331 is the blade. Pushing the lower end of the connecting portion 3112d of 3112b, thereby causing the edge portion 3112c of the blade 3112b to be further away from the connecting plate 3112a to allow the clamping space 3314 to remain open. get away Next, the clamp module 323 is driven by the first moving module 321 and the second moving module 322 to cause the source bobbin seal 62 to be temporarily separated from the clamping space 3314 . Therefore, in the process of removing the lower thread 60 , the source lower thread 62 is temporarily separated from the clamping space 3314 , so that the excess of the bobbin thread 60 is caused during rotation of the first transmission member 3112 , the thread gripper It can be prevented from being withdrawn from (15). Then, after the removal of the bobbin seal 60 is completed, the first and second moving modules 321 and 322 drive the clamp module 323 to move, which causes the source bobbin seal 62 to move into the clamping space 3314 . ) to return to the inside. Then, the ejection drive source 332 drives the ejection lever 331 to swing, which causes the pushing portion 3312 of the ejection lever 331 to move away from the lower end of the connecting portion 3112d of the blade 3112b. and, thereby, the blade 3112b causes the edge portion 3112c of the blade 3112 and the connecting plate 3112a to collectively clamp the source bobbin seal 62 through its own elastic force.

The above-described embodiments are used to conveniently explain the present invention, and do not further limit the present invention. Without departing from the concept of the present disclosure, to those skilled in the art, simple modifications or changes may be made in accordance with the claims and detailed description of the present disclosure, and should be included within the protection scope of the present disclosure. do.

Claims (14)

In the bobbin thread introducing device capable of mounting a bobbin thread with a bobbin and a bobbin case,
a first operation module comprising a first transmission member and a first drive source operable to rotate the first transmission member, wherein the bobbin is driven to rotate synchronously by the first transmission member, which bobbin thread is wound around the bobbin;
bobbin thread clamping mechanism - a clamp module having a movable clamp and a fixed clamp that can be repositioned - when the clamp module is in the clamping position, both the movable clamp and the fixed clamp cause the bobbin thread to lock the clamp clamping the bobbin seal in a loose state to prevent disengagement from the module, a first moving module operable to move the clamp module along a first path from the clamping position to a first ready position; moving the clamp module from the first ready position to the first guiding position along a second path intersecting the first path, so that the bobbin thread is in contact with the open end of the bobbin case, and is tensioned from the loose state comprising a second movement module operable to be transformed into a tensioned state; and
a second operation module comprising a second transmission member and a second driving source operable to rotate the second transmission member, wherein the bobbin case is driven to rotate synchronously by the second transmission member, thus and the bobbin thread in the tensioned state is introduced into a thread guiding slot formed on the bobbin case from the open end by the rotating bobbin case.
According to claim 1,
The first transmission member is provided with a blade (blade),
When the clamp module moves from the first ready position to the first guiding position, the bobbin thread is in contact with the blade.
3. The method of claim 2,
When the clamp module moves to the first guiding position, the first transmission member drives the blade to rotate to cut the bobbin thread.
4. The method of claim 3,
wherein the bobbin yarn introducing device further has a yarn release mechanism, the yarn release mechanism comprising a release lever and a release drive source;
the release lever is spaced from the first transmission member and the release drive source is capable of driving the release lever to selectively move the release lever closer to or away from the first transmission member, thus , when the release lever pushes the blade, the blade moves relative to the first transmission member, whereby the clamping space between the blade and the first transmission member is in an open state into which the bobbin seal enters. A bobbin thread introducing device showing .
According to claim 1,
In the bobbin thread introducing device, a bobbin thread control mechanism is further provided between the first operation module and a thread gripper,
wherein the bobbin yarn control mechanism has an adjustable drive source capable of generating power and an adjustment member driven to move toward or away from the bobbin yarn by the adjustable drive source;
When the adjusting member is brought close to the bobbin seal, the adjusting member may restrict the bobbin seal to be close to the clamp module, which introduces the bobbin seal causing the clamp module to clamp the bobbin seal in the clamping position. Device.
According to claim 1,
the first moving module is coupled to the second moving module,
When the second moving module drives the clamp module to move along the second path, the first moving module simultaneously moves.
7. The method of claim 6,
The second moving module drives the first moving module and the clamping module to move away from the first guiding position, which causes the clamping module to move the second along a third path parallel to the second path. move to the ready position,
The first moving module drives the clamp module to move the clamp module from the second ready position to a second guiding position along a fourth path parallel to the first path, whereby the bobbin seal is placed on the bobbin case. A bobbin thread introducing device for bringing into contact with a formed hook arm.
8. The method of claim 7,
When the clamp module is in the second guiding position, the second transmission member rotates to introduce the bobbin thread into a thread hole formed on the hook arm.
9. The method of claim 8,
The bobbin case further has a thread blocking piece capable of restricting the bobbin thread to the thread hole,
The seal blocking piece has an elastically deformable elastic arm,
The elastic arm is positioned at one side of the hook arm to prevent the bobbin thread from being separated from the thread hole.
According to claim 1,
the first movement module has a jaw transmission member connected to the clamp module and a clamp drive source connected to the jaw transmission member;
the jaw transfer member and the clamp drive source are connected together to an avoidance unit;
When the clamp module moves to the clamping position along the first path, the avoiding unit may simultaneously change the relative position between the bobbin case and the jaw transfer member, the clamp drive source or the clamp module, thus, When the clamp module moves to the clamping position along the first path, the clamp module does not contact the bobbin through the avoiding unit.
11. The method of claim 10,
The avoidance unit is
a guide wheel coupled to the jaw transfer member;
an assembling plate comprising a curved guide rail in contact with the guide wheel;
a swinging plate assembled to the clamp drive source and pivotally connected to the assembly plate; and
a holding member positioned between the assembly plate and the swing plate;
The retaining member may generate a holding force acting on the swing plate, which causes the swing plate to swing relative to the assembly plate through the holding force, whereby the guide wheel causes the curved guide wheel bobbin thread introduction device in continuous contact with
12. The method of claim 11,
the avoiding unit further comprises a roller capable of being brought into contact with the jaw transfer member;
When the roller comes into contact with the first moving module, the swing plate swings to drive the guide wheel apart from the curved guide rail.
12. The method of claim 11,
the fixing clamp is fixed to the jaw transfer member;
one of the movable clamp and the fixed clamp has a clamping groove, and the other of the movable clamp and the fixed clamp has a clamping block;
when the clamp module clamps the bobbin thread, the clamping block moves into the clamping slot, so that the clamping block and the clamping slot jointly clamp a partial length of the bobbin thread.
The sewing machine according to any one of claims 1 to 13, comprising a bobbin and a bobbin thread introducing device capable of attaching a bobbin thread to a bobbin case,
a sewing machine body having a rotary hook; and
A sewing machine comprising a bobbin exchange device assembled to the sewing machine body, the bobbin capable of being assembled from the rotary hook to the bobbin thread introducing device.

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