JP4004557B2 - Bobbin thread removal device - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to an apparatus for removing residual yarn from a bobbin.
[0002]
[Prior art]
In a sewing machine that performs sewing using an upper thread and a lower thread, especially an industrial sewing machine that performs high-speed sewing work, it is necessary to frequently replace the bobbin around which the lower thread is wound. Generally, when the bobbin thread is consumed or when the remaining capacity is low, the sewing machine operation is temporarily stopped, the bobbin case is removed from the hook, the bobbin remaining thread is removed, and the bobbin is wound around the bobbin. A series of operations for manually storing the newly wound bobbin in the bobbin case and mounting the bobbin case in the hook is performed manually.
[0003]
However, such a residual yarn removing operation, a bobbin winding operation on a bobbin, and a bobbin case replacement operation are extremely inefficient and cause a decrease in productivity. In view of this, the present applicant has attempted to solve the above-described problems in the lower thread automatic feeding apparatus described in Japanese Patent Application Laid-Open No. 7-68071 filed earlier.
[0004]
The outline configuration of the lower thread automatic supply device described in Japanese Patent Application Laid-Open No. 7-68071 includes a bobbin case in which a bobbin around which a lower thread is wound is accommodated in a sewing machine hook, and the bobbin case is gripped. Alternatively, a bobbin case gripping means that can be opened and a bobbin exchanging device comprising a pivot arm that rotates the bobbin case gripping means about one axis and is movable in the axial direction, and an axial distance from the hook. A lower yarn winding device for winding the lower yarn around the bobbin, and a residual yarn removing device for removing the residual yarn from the bobbin.
[0005]
The residual yarn removing device described in the publication includes a yarn removing shaft and winding means composed of a plurality of elastic linear bodies that are fixed around the yarn removing shaft and arranged around the yarn removing shaft and project in the axial direction. Receiving the winding means facing the winding means and extending the elastic linear body outward with the fixed end as a fulcrum, and rotating together with the winding means, the receiving shaft and the winding An air nozzle that is further disposed on the side opposite to the bobbin case and that blows the lower thread end that hangs down from the bobbin case that houses the bobbin to the working position, and the lower thread end that is blown to the working position The remaining yarn wound around the winding means is guided between the guide member that can be sandwiched between the shaft and the winding means and the winding means that is disposed around the winding means and moves backward. A residual yarn removing device comprising a handling plate that can be handled off The lower yarn end portion of a predetermined length (about 35 to 40 mm) that is led out from the bobbin case and hangs down is blown to the working position by the air nozzle, and the lower yarn end portion blown to the working position is Guided by a guide member, sandwiched between the receiving shaft and the thread removal shaft, and by rotating the winding means for a predetermined time, the remaining thread wound around the bobbin is wound around the elastic linear body. Thereafter, by retracting the winding means and removing the elastic linear body from the receiving shaft, the expanded elastic linear body is returned to its original position, and the elastic linear body and the remaining yarn wound up are returned. And the remaining yarn taken up by the handling plate is dropped and removed by removing the remaining yarn downward.
[0006]
In the bobbin thread automatic supply device, the bobbin case gripping means is connected to the hook and the remaining yarn removing device by a rotating operation using one axis of the rotating arm as a fulcrum and a moving operation parallel to the one axis. The remaining thread removal position is movable to the lower thread winding position in the lower thread winding device, and the bobbin winding operation, the remaining thread removal operation, and the bobbin case replacement operation are automatically performed. As a result, work efficiency and productivity can be improved.
[0007]
[Problems to be solved by the invention]
However, the apparatus described in Japanese Patent Laid-Open No. 7-68071 has the following problems. That is, in the above-described residual thread removing device, the lower thread end portion of a predetermined length (about 35 to 40 mm) derived from the bobbin case (specifically, under the lower thread tension spring) is disposed between the receiving shaft and the thread removing shaft. In order to increase the probability of clamping, it is desirable to bring the winding means close to the thread end outlet of the bobbin case. In this way, the winding means is connected to the bobbin case thread. Since the remaining yarn is wound around the winding means when approaching the end outlet, the wound and swollen remaining yarn comes into contact with the bobbin case, and the winding amount is limited. There is a problem.
[0008]
That is, if the winding means is brought close to the yarn end outlet of the bobbin case in order to improve the yarn end clamping rate, the remaining yarn winding amount is limited, and not all the remaining yarn can be removed, while all the remaining yarn must be removed. When the winding means is moved away from the yarn end outlet of the bobbin case, there is a conflicting problem that the yarn end clamping rate is reduced and the remaining yarn is not reliably removed.
[0009]
Further, as described above, the guide member that guides the lower thread end portion of the predetermined length led out from the bobbin case so as to be sandwiched between the receiving shaft and the winding means is provided from the thread end outlet port of the bobbin case. Since the yarn end is arranged at a distance, the guide of the yarn end is unstable, and the yarn end cannot be pinched between the receiving shaft and the winding means.
[0010]
In addition, the above-described residual yarn removing apparatus has a problem that the cost is increased due to the use of complicated parts such as the elastic linear body and the large number of parts.
[0011]
Therefore, the present invention can automatically remove all bobbin remaining yarns with a simple configuration and reduce the cost by minimizing the number of actuators (driving means) necessary for the remaining yarn removing operation. Another object of the present invention is to provide a bobbin remaining yarn removing device capable of improving the degree of design freedom by creating an empty space.
[0012]
[Means for Solving the Problems]
In order to achieve the above object, the bobbin residual yarn removing device according to claim 1 is capable of moving to a bobbin that is rotatably supported, a position below the bobbin, and a position where the bobbin abuts and a position where the bobbin abuts. The bobbin thread that hangs down from the bobbin due to the movement from the contacted position to the separated position edge The lower thread is secured by moving from the separated position to the abutted position while ensuring a space for lower thread introduction through which the thread enters. edge Hold the clamped bobbin thread From the edge A pair of rotatable to entrain and eject roller And this pair roller One drive means for rotating one or both of the lower thread discharge rotation direction or the reverse direction of the lower thread discharge rotation direction; roller When the rotation direction is the lower thread discharge rotation direction, the pair of roller To the position where the roller When the rotation direction is opposite to the lower thread discharge rotation direction, the pair of roller So that the driving force of the driving means is moved to the position where the pair is separated. roller Driving force transmitting means for transmitting to the motor.
In order to achieve the above object, the bobbin residual thread removing device according to claim 2 is capable of moving to a bobbin that is rotatably supported, a position below the bobbin, and a position where the bobbin abuts and a position where the bobbin abuts. The bobbin thread that hangs down from the bobbin due to the movement from the contacted position to the separated position edge The lower thread is secured by moving from the separated position to the abutted position while ensuring a space for lower thread introduction through which the thread enters. edge Hold the clamped bobbin thread From the edge A pair of rotatable rollers to entrain and discharge; roller One of roller Or both roller A driving means for rotating the lower thread discharging rotation direction or the direction opposite to the lower thread discharging rotation direction; roller One of roller A rotating arm supported so as to be rotatable about one axis, and the other arm about the one axis. roller Said one roller Biasing means for biasing toward roller When rotating in the direction opposite to the lower thread discharge rotation direction, the pair of driving means roller While rotating the rotating arm in the direction of separating the roller When rotating in the lower thread discharge rotation direction, the pair of biasing force is applied by the biasing means. roller Pivoting the pivot arm in the direction in which the roller Driving force transmitting / blocking means for blocking the driving force by the driving means from the rotating arm so that the pressing force comes into contact with the rotating arm.
[0013]
In order to achieve the above object, the claims 3 The bobbin residual thread removing device of claim 2 In addition, the driving force is transmitted to the rotating arm by the driving force transmitting / blocking means via a cam.
[0014]
In order to achieve the above object, the bobbin residual yarn removing device according to claim 4 is capable of moving to a bobbin that is rotatably supported, a position below the bobbin, and a position where the bobbin abuts and a position where the bobbin abuts. The bobbin thread that hangs down from the bobbin due to the movement from the contacted position to the separated position edge The lower thread is secured by moving from the separated position to the abutted position while ensuring a space for lower thread introduction through which the thread enters. edge Hold the clamped bobbin thread From the edge A pair of rotatable to entrain and eject roller And this pair roller One of the rollers or both roller A driving means for rotating the lower thread discharging rotation direction or the direction opposite to the lower thread discharging rotation direction; roller One of roller And a pair of rotating arms supported so as to be rotatable about one axis and the pair of the pair of rollers by the driving means during rotation in a direction opposite to the lower thread discharge rotation direction of the roller. roller While rotating the rotating arm in the direction of separating the roller When rotating in the lower thread discharge rotation direction, the pair of roller The pivoting arm is pivoted in the direction in which the two abut and the pair of roller Driving force transmitting means for transmitting the driving force by the driving means to the rotating arm so as to hold the pressing force by the rotating arm when the is in a pressed state.
[0015]
[Action]
According to such a bobbin residual yarn removing device in claim 1, a pair of roller Is rotated in the direction opposite to the lower thread discharge rotation direction by the driving means, a pair of driving force transmission means from the driving means by the driving force transmission means roller The driving force is transmitted to the rotating arm that supports the rotating arm, and the rotating arm has the above-mentioned pair of axes as a fulcrum. roller Rotate in the direction of separating roller A space for introducing the bobbin thread is secured between the bobbin threads, and the bobbin thread hangs down from the bobbin between these spaces. edge On the contrary, the above pair of roller Is rotated in the lower thread discharge rotation direction by the driving means, the driving force is interrupted from the driving means to the rotating arm by the driving force transmitting means. roller Rotate so that roller Both pressed roller Between lower thread edge The bobbin remaining thread roller Is involved and discharged. Therefore, roller There is no limit to the amount of remaining yarn discharged by the wrapping.
Also, roller Entangles and discharges the yarn end. roller Also has the function of thread end guide.
It also has the function of thread end guidance. roller Is roller Since it is not the structure which winds up a remaining thread around, it can arrange | position close to the thread end outlet of a bobbin case.
Further, the apparatus has no complicated parts such as an elastic linear body, and the number of parts is small.
One side roller Since the drive means for driving and the drive means for rotating arm are not provided separately, but both are driven by one drive means, the number of parts is smaller than that provided separately. As it becomes less, free space becomes available.
In addition, according to the bobbin residual yarn removing device according to claim 2, roller Is rotated in the direction opposite to the lower thread discharge rotation direction by the driving means, a pair of driving force transmission / cutoff means from the driving means to the pair of roller The driving force is transmitted to the rotating arm that supports the rotating arm, and the rotating arm has the above-mentioned pair of axes as a fulcrum. roller Rotate in the direction of separating roller A space for introducing the bobbin thread is secured between the bobbin threads, and the bobbin thread hangs down from the bobbin between these spaces. edge On the contrary, on the contrary, roller Is rotated by the driving means in the lower thread discharge rotation direction, the driving force is interrupted from the driving means to the rotating arm by the driving force transmission / interruption means. Arm is centered on one axis roller Rotate so that roller Both pressed roller Between lower thread edge The bobbin remaining thread roller Is involved and discharged. Therefore, roller There is no limit to the amount of remaining yarn discharged by the wrapping.
Further, since the rotating body entrains and discharges the yarn end, the rotating body also has the function of guiding the yarn end.
It also has the function of thread end guidance. roller Since the remaining yarn is not wound around the rotating body, it can be disposed close to the yarn end outlet of the bobbin case.
Further, the apparatus has no complicated parts such as an elastic linear body, and the number of parts is small.
One side roller Since the drive means for driving and the drive means for rotating arm are not provided separately, but both are driven by one drive means, the number of parts is smaller than that provided separately. As it becomes less, free space becomes available.
[0016]
According to the bobbin residual yarn removing device of claim 3, when the driving force is transmitted to the rotating arm by the driving force transmitting / blocking means via the cam, roller Against the other roller The opening angle of the rotating arm when the two are separated from each other is set according to the cam shape.
[0017]
According to the bobbin residual yarn removing device of claim 4, roller Is rotated in the direction opposite to the lower thread discharge rotation direction by the driving means, a pair of driving force transmission means from the driving means by the driving force transmission means roller The driving force is transmitted to the rotating arm that supports the rotating arm, and the rotating arm has the above-mentioned pair of axes as a fulcrum. roller Rotate in the direction of separating roller A space for introducing the bobbin thread is secured between the bobbin threads, and the bobbin thread hangs down from the bobbin between these spaces. edge On the contrary, when the rotating body is rotated in the lower thread discharge rotation direction by the driving means, the driving force is transmitted from the driving means to the rotating arm by the driving force transmitting means. , One pair as a fulcrum roller Rotate in the direction toward the lower thread between the rotating bodies edge A pair of these roller Is in a pressing state, the driving force is transmitted from the driving means to the rotating arm while sliding, so that the pressing force is maintained. roller Continues rotating in the lower thread discharge rotation direction without any support, and the bobbin remaining thread is entrapped and discharged by the cooperation of both rotating bodies. Therefore, roller There is no limit to the amount of remaining yarn discharged by the wrapping.
Also, roller Entangles and discharges the yarn end. roller Also has the function of thread end guide.
It also has the function of thread end guidance. roller Since the remaining yarn is not wound around the rotating body, it can be disposed close to the yarn end outlet of the bobbin case.
Further, the apparatus has no complicated parts such as an elastic linear body, and the number of parts is small.
One side roller Since the drive means for driving and the drive means for rotating arm are not provided separately, but both are driven by one drive means, the number of parts is smaller than that provided separately. As it becomes less, free space becomes available.
[0018]
【Example】
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. As shown in FIGS. 1 and 10, the lower thread automatic supply device of this embodiment includes a lower thread winding device 162, a remaining thread removing device 161, a lower thread winding position C, and a remaining thread winding position 162. A bobbin exchanging device 160 capable of moving the bobbin case 2 to a residual thread removing position B of the yarn removing device 161, a hook position (bobbin case attaching / detaching position) A, and a bobbin case attaching / detaching position D of the dummy shaft (bobbin case holding means) 6; The lower thread automatic supply device is provided at the lower part of the sewing machine bed 101. First, the bobbin exchanging device 160 will be described below with reference to FIGS.
[0019]
11 to 15, reference numeral 1 is a hook to which the bobbin case 2 is mounted, 1 a is a hook shaft, 3 is a main base attached to the sewing machine body, and is disposed directly below the hook 1. A base plate is shown as a support, and a base end 4 a of a transport shaft 4 having an axis parallel to the shuttle shaft 1 a is fixed to the base plate 3, and the transport shaft 4 is separated from the base plate 3. It is in a state of being supported.
[0020]
On the front end 4b side (on the side opposite to the base plate) of the transport shaft 4, a transport block 12 (FIG. 11) is formed so that the outer peripheral surface of the hollow cylinder is cut at two locations along the axial direction and the cut surfaces face each other. Is supported so as to be rotatable and slidable with respect to the conveying shaft 4.
[0021]
One plate-like portion constituting the L-shape of the conveyance plates 10 and 10 bent in an L-shape is fixed to each cut surface of the conveyance block 12, and the other plate-like shape constituting the L-shape. As shown in FIG. 11, the portions are in a state of being opposed to each other across the axis.
[0022]
One end of each of the holding portions 11, 11 bent to the hook side along the axial direction is fixed to each of the transport plates 10, 10, and the other end of these holding portions 11, 11 ( Bobbin case gripping means (not shown) capable of gripping or opening the bobbin case are fixed to the end facing the hook side. As the bobbin case gripping means, for example, an automatic lower thread supply device disclosed in Japanese Patent Application Laid-Open No. 5-192476 or an automatic lower thread supply device of a sewing machine disclosed in Japanese Patent Application No. Hei 5-121960 previously filed by the present applicant. As well as a pair of electromagnet attracting heads that have been used, for example, by means of a lever claw described in the lower thread automatic feeding device of the sewing machine of Japanese Patent Application No. 5-116363 previously filed by the present applicant, etc. What is essential is that the bobbin case 2 can be attached to and detached from the opposing member (for example, the hook 1) as necessary.
[0023]
A rotating gear 13 is fixed to the outer periphery of the transport block 12, and a driving gear 19 having a shape elongated along the hook shaft 1a direction is provided on the rotating gear 13, as shown in FIG. Meshed. One end of the drive gear 19 is rotatably supported by the portion of the motor fixing plate 21 attached to the base plate 3 that protrudes to the other end of the conveying shaft, and the other end is fixed to the motor fixing plate 21. In this state, the rotation motor 20 is directly connected to the output shaft.
[0024]
Therefore, when the rotation motor 20 rotates, the rotation arm 70 composed of the conveyance block 12, the conveyance plates 10 and 10 and the holding portions 11 and 11 is rotated via the drive gear 19 and the rotation gear 13. It has become. In this embodiment, the rotating operation of the rotating arm 70 is performed when the rotating arm 70 is at the retracted position (see FIGS. 12 to 14). Further, although the transport shaft 4 is cantilevered, since it is guided by the drive gear 19, its support strength is sufficient.
[0025]
For example, a stop ring (not shown) is fixed to the fixed end side of the conveying shaft 4 from the rotating gear 13 on the outer periphery of the conveying block 12, and the rotating gear 13 and the stop ring on the outer periphery of the conveying block 12 are fixed. In between, the linear motion collar 14 is rotatably supported.
[0026]
As shown in FIGS. 11 to 13, one end of a rack 16 that is supported so as to be movable in parallel with the shuttle shaft 1 a is fixed to the linear movement collar 14, and a pinion is attached to the other end of the rack 16. 17 meshes. The pinion 17 is fixed to the output shaft of the moving motor 18 attached to the base plate 3.
[0027]
Therefore, when the moving motor 18 is driven, the linear motion collar 14 and the rotating arm 70 are moved along the axial direction of the transport shaft 4 together with the rack 16 via the pinion 17. That is, the rotation arm 70 can rotate with respect to the transport shaft 4 and can slide along the transport shaft 4.
[0028]
A sensor fixing plate 33 is attached to the open end side of the transport shaft 4, and a rotation sensor 31 including a light emitting element 31 a and a light receiving element 31 b is attached on the sensor fixing plate 33. Further, as shown in FIGS. 11 and 12, a sensor plate 32 is fixed to the rotating arm 70. When the rotating arm 70 is rotated, the sensor plate 32 is connected to the light emitting element 31a and the light receiving element 31b. The position of the rotation sensor 31, the sensor fixing plate 33, and the sensor plate 32 is adjusted so as to pass between the two.
[0029]
As shown in FIGS. 11 and 13, a linear motion sensor 41 having the same structure as the rotation sensor 31 is attached to the base plate 3. A sensor plate 15 is fixed to the rack 16, and the sensor plate 15 can pass between the light emitting element 41 a and the light receiving element 41 b of the linear motion sensor 41 when the rotating arm 70 is linearly moved. As described above, the positions of the linear motion sensor 41 and the sensor plate 15 are adjusted.
[0030]
In addition, a dummy shaft 6 as a bobbin case holding means is fixed at a position D on the base plate 3 opposite to the rotation locus of the bobbin case gripping means, as shown in FIG. ing. As shown in FIG. 15, the dummy shaft 6 has the same structure as the inner hook shaft 5, and can hold the bobbin case 2 by pushing in the bobbin case 2 in which the bobbin is accommodated. . Then, the existing bobbin locking claw 2d of the pushed-in bobbin case 2 is engaged with the locking groove of the rotation preventing member 5aa projecting in the vicinity of the dummy shaft 6 as shown in FIGS. It is configured to That is, the bobbin case 2 is positioned and held at a predetermined position.
[0031]
By the way, the lower thread winding position C and the remaining thread removal position B are rotated when the sewing machine bed 101 is raised from the upright plane along the range V below the conveying shaft 4 and the coaxial line, as shown in FIG. It is the range W on the fulcrum 103 side, and is disposed at a position opposite to the rotation locus of the bobbin case gripping means. The remaining yarn removal position B is arranged below the lower yarn winding position C. Further, the position of the residual yarn removal position B in the conveyance axis direction (direction perpendicular to the paper surface in FIG. 10) is the retracted position of the bobbin case gripping means, and the position of the lower thread winding position C in the conveyance axis direction is the bobbin case gripping means. Is at a position slightly advanced from the retracted position (position advanced toward the paper surface in FIG. 10) (refer to FIG. 1 for the positions of the remaining yarn removing position B and the lower yarn winding position C in the axial direction). In FIG. 10, reference numeral 102 denotes a sewing machine table, 106 denotes an oil pan, 104 and 105 denote lower shafts, and X denotes a rotation trajectory on the outer periphery side when the sewing machine head is raised.
[0032]
A lower thread winding device 162 is disposed at the lower thread winding position C. As shown in FIG. 1, the lower thread winding device 162 drives a winding motor (not shown) to transmit this rotational driving force via a motor shaft pulley 200, a timing belt 201, and a winding pulley 202. The bobbin 7 accommodated in the bobbin case 2 which is transmitted to the winding clutch plate 203 and the clutch pawl of the winding clutch plate 203 is conveyed to the lower thread winding position C by the bobbin changing device 160 is provided. A configuration is adopted in which the bobbin 7 can be automatically wound around the bobbin 7 by rotating the bobbin 7 by clutching in the hole 7b (see FIG. 5). Further, by driving a threading motor (not shown), this rotational driving force is rotatably arranged around the bobbin case 2 set at the lower thread winding position C via the moving knife rotating gear 206. The lower knife threaded around the bobbin 7 and led out from the bobbin case opening is transmitted to the bobbin case 2 by transmitting to the moving knife threader 204 and rotating the moving knife threader 204 around the bobbin case 2. The thread can be hooked so as to be led out from the lower thread outlet hole under the lower thread tension spring. Furthermore, the lower thread led out from the lower thread outlet hole under the lower thread tension spring is spun by the rotational movement of the moving knife threading 204, and the lower thread under the lower thread tension spring is fixed with the fixed knife 205. The lower thread led out from the outlet hole can be cut with respect to the lower thread supply source (not shown). Incidentally, the lower thread winding device (including the thread hooking and thread trimming mechanism) 162 is not limited to the one having the above-described configuration, and can automatically wind the lower thread around the bobbin 7, Any device can be used as long as it is capable of thread trimming. Appropriate ones can be employed, such as the bobbin changing device of the sewing machine and the bobbin winding device described in the bobbin changing device of the sewing machine described in Japanese Patent Application No. 5-116363.
[0033]
A residual yarn removing device 161 is disposed at the residual yarn removing position B. The remaining yarn removing device 161 will be described below with reference to FIGS. 1 and 2.
[0034]
In the figure, reference numeral 79 denotes a rotation axis. The rotary shaft 79 penetrates the base plate 3 and is rotatably spanned on both side plates 80a and 80b of a U-shaped residual yarn bracket 80 disposed so as to sandwich the base plate 3. Both ends protrude outward from the side plates 80a and 80b. A driving roller 760 as a rotating body is fixed to a shaft portion that protrudes from the front side (left side in FIG. 1) side plate 80a of the remaining yarn bracket 80, and a shaft portion that protrudes from the back side (right side in FIG. 1) side plate 80b The remaining yarn roller driving pulley 83 is fixed. A motor bracket 3a is disposed on the back side of the base plate 3, and a remaining yarn winding motor 86 is fixed to the motor bracket 3a. A residual yarn winding pulley (not shown) is fixed to the output shaft of the residual yarn winding motor 86, and a residual yarn belt (not shown) is stretched between the residual yarn winding pulley and the residual yarn roller driving pulley 83. ing.
[0035]
Accordingly, when the residual yarn winding motor 86 is driven, the rotation is transmitted to the rotary shaft 79 via the residual yarn winding pulley, the residual yarn belt, and the residual yarn roller driving pulley 83, so that the driving roller 760 is rotated. .
[0036]
Further, between the side plate 80a of the remaining yarn bracket 80 and the base plate 3, a rotating arm 85 as a U-shaped rotating arm is disposed as shown in FIG. A rotary shaft 80c is rotatably spanned on both side plates 85a and 85b constituting the U-shape of the rotary arm 85, and a shaft portion protruding further toward the front side from the front side plate 85a serves as a rotating body. A driven roller 761 is fixed. A shaft 87 disposed in parallel to the shuttle shaft 1a is fixed to the lower portion of the rotary arm 85. The shaft 87 penetrates the base plate 3 and is rotatably supported on both side plates 80a and 80b of the remaining yarn bracket 80. The shaft 87 is always attached to the middle portion of the shaft 87 in FIG. A torsion coil spring 210 is provided as an urging means for urging in the counterclockwise direction (CCW direction).
[0037]
A one-way clutch 211 serving as a driving force transmission / cut-off means is provided on the outer periphery of the shaft portion of the shaft 87 that protrudes further from the back side plate 80b, and a rotary arm drive is provided on the outer periphery of the one-way clutch 211. A gear 88 is fixed. The one-way clutch 211 is locked when a rotational drive force in the clockwise direction (CW direction) in FIG. 2 is applied from the rotary arm drive gear 88, and transmits the drive force in the rotational direction to the shaft 87, while the rotary arm When the rotational driving force in the counterclockwise direction (CCW direction) in FIG. 2 is applied from the driving gear 88, the locked state is released and the driving direction in the same direction becomes free and the driving force in the rotational direction is cut off from the shaft 87. It is configured. A rotating arm transmission gear 91 is engaged with the rotating arm drive gear 88, and the rotating arm transmission gear 91 is fixed to an intermediate portion of the rotating shaft 79.
[0038]
Accordingly, when the residual yarn winding motor 86 is driven in the CCW direction in FIG. 2, the rotation is transmitted to the rotary arm transmission gear 91 via the residual yarn winding pulley, the residual yarn belt, and the residual yarn roller driving pulley 83, so that the rotary arm The rotation direction is changed to the CW direction in FIG. 2 through the drive gear 88, and this rotation driving force is transmitted to the shaft 87 by the one-way clutch 211, and the rotary arm 85 is moved to the CW in FIG. It is designed to rotate in the direction.
[0039]
Further, when the remaining yarn winding motor 86 is driven in the CW direction in FIG. 2, the rotation is transmitted to the rotating arm transmission gear 91 via the remaining yarn winding pulley, the remaining yarn belt, and the remaining yarn roller driving pulley 83 to drive the rotating arm. The rotation direction of the gear 88 is changed to the CCW direction in FIG. 2, and this rotational driving force is cut off from the shaft 87 by the one-way clutch 211, so that the rotary arm 85 is free from the CCW direction in FIG. It is supposed to be.
[0040]
Note that the side plate 80a has a side plate 80a so that the rotary shaft 80c for fixing the driven roller 761 does not hit the front side plate 80a of the remaining yarn bracket 80 when the rotary arm 85 and the driven roller 761 rotate about the shaft 87. Notches and the like are appropriately formed.
[0041]
In addition, air is supplied to the remaining thread removing device 161 toward the lower thread leading portion (the lower thread leading portion of the lower thread tension spring) of the bobbin case 2 set at the remaining thread removing position B by the rotating arm 70. An air nozzle 100 for thread dropping that can be sprayed is provided (see FIG. 2). The air dripping air nozzle 100 is used to reliably hang down the bobbin thread led out from the bobbin case 2 lower thread lead-out portion and attached to the bobbin case 2 by the air force. A solenoid valve (not shown) is connected to the air nozzle 100 for thread drop, and the air blowing of the air nozzle 100 for thread drop is controlled by the solenoid valve.
[0042]
Further, as shown in FIG. 2, the rotating arm 70 of the bobbin exchanging device 160 described above has a lower thread end M that hangs down from a bobbin case 2 (specifically, under a lower thread tension spring) in which the bobbin 7 is housed. The air nozzle 151 for blowing the air toward the work position is fixed. The working position referred to here is a position where the lower thread end portion M is in contact with the outer peripheral surface of the drive roller 760 (more precisely, the lower outer peripheral surface in the drawing) and flows downstream (see FIG. 2B). The lower thread end M is blown toward the working position by blowing air from the air nozzle 151 toward the outer peripheral surface of the bobbin case 2 and toward the outer peripheral surface of the drive roller 760 along the outer peripheral surface. This is achieved by creating a flow. An electromagnetic valve (not shown) is connected to the air nozzle 151, and the air nozzle 151 is configured such that the air blowing is controlled by the electromagnetic valve.
[0043]
Further, as shown in FIG. 1, for example, a reflection type optical sensor 500 as rotation detecting means is attached to the front side plate 80a of the bracket 80 in the residual yarn removing device 161. The reflection type optical sensor 500 has a bobbin 7 as shown in FIG. 5 when the bobbin case 2 is set at the remaining thread removal position B and is opposed to the reflective optical sensor 500 (when the remaining thread can be removed). It is arranged so as to face the reflection hole 7a drilled at one place on the side surface.
[0044]
Therefore, when the bobbin 7 is rotated by the residual yarn removing operation by the residual yarn removing device 161, a continuous pulse wave is output from the reflective optical sensor 500 as shown in FIG. Here, if the bobbin thread is removed from the bobbin 7, the rotation of the bobbin 7 is stopped. Therefore, the output from the reflection type optical sensor 500 indicates the completion of the remaining thread removal.
[0045]
As described above, the residual yarn removing device 161 is configured, and is basically configured to pull out the lower yarn that is wound around the bobbin 7 and hangs down from the bobbin case 2, and its main part is below the residual yarn removing position B. (Refer to FIG. 1).
[0046]
Next, the operation of the bobbin thread automatic feeding device configured as described above will be described below. First, for example, in order to cause one bobbin case gripping means to grip a bobbin case containing a bobbin wound with a lower thread, a hand is inserted from the rotating arm side (front side; left side in FIG. 1), The bobbin case containing the bobbin that has already been rotated is pushed into the dummy shaft 6 without returning the palm in the same manner as when the bobbin case is mounted on the inner hook shaft 5, and the bobbin case is mounted on the dummy shaft 6. Here, for convenience of explanation, the bobbin case code 2X is used, and the bobbin case code 2Y described below is used.
[0047]
Next, when the power switch is turned on, the rotating arm 70 is returned to the origin position, and when the start switch is turned on, the rotating arm 70 is rotated so that one bobbin case gripping means faces the dummy position D. Then, the rotating arm 70 is moved forward, and the bobbin case 2X accommodating the bobbin wound with the lower thread wound held by the dummy shaft 6 is gripped by one bobbin case gripping means. At this time, the other bobbin case gripping means goes to the hook without interfering with any obstacle.
[0048]
Here, when the dummy shaft 6 is provided at a position opposite to the remaining yarn removing position B and the lower yarn winding position C around the conveying shaft 4, the remaining yarn removing position B is as described above. The position in the conveying axis direction is at the retracted position of the bobbin case gripping means, and the position in the conveying axis direction of the bobbin winding position C is at a position where the bobbin case gripping means is slightly advanced from the retracted position. When the bobbin case holding means is directed toward the dummy shaft 6, the other bobbin case holding means collides with the remaining yarn removing device 161 and the lower yarn winding device 162. However, in this embodiment, there is no problem because the dummy shaft 6 is disposed at a position opposite to the rotation locus of the bobbin case gripping means and directly below the hook 1 as described above.
[0049]
Then, the rotating arm 70 is retracted and rotated so that one bobbin case gripping means gripping the bobbin case 2X is opposed to the hook 1 and moved forward, and the bobbin case 2X containing the bobbin wound with the lower thread is accommodated. Is installed in the hook. At this time, the other bobbin case holding means moves toward the dummy shaft 6 without interfering with any obstacle. Then, the rotating arm 70 is retracted. At this time, the operator inserts his hand from the side of the rotating arm again in the same manner as described above, and attaches the bobbin case 2Y accommodating the bobbin wound with the lower thread to the dummy shaft 6.
[0050]
Next, when sewing is started, a bobbin case 2Y in which the bobbin case wound around the bobbin thread held by the dummy shaft 6 is accommodated in one of the bobbin case gripping means by the same operation as described above during the sewing. And the revolving arm 70 is retracted.
[0051]
When predetermined sewing is completed in this state (step 1), the bobbin case 2 is replaced in step 2.
[0052]
That is, the bobbin case holding means that does not hold the bobbin case is moved forward, the bobbin case 2X that accommodates the bobbin with less residual yarn is taken out from the hook, and the rotating arm 70 is moved backward. Next, the rotary arm 70 is rotated so that the bobbin case 2Y accommodating the bobbin wound with the lower thread is opposed to the hook 1 and moved forward, and the bobbin case 2Y accommodating the bobbin wound with the lower thread is mounted in the hook. Then, the rotating arm 70 is retracted.
[0053]
Then, the process proceeds to Step 3, and when the sewing is started in Step 3, the rotary arm 70 is rotated during the sewing, and the bobbin case 2X containing the bobbin with the remaining thread reduced is set to the remaining thread removal position B. To turn.
[0054]
At this time, the rotary arm 85 is in the position shown in FIG. 2C, that is, the position where the driving roller 760 and the driven roller 761 come into contact. Then, the process proceeds to step 4, where the remaining yarn winding motor 86 is driven in the CCW direction in FIG. 2 to rotate the drive roller 760 in the same direction and the rotation direction is reversed by the rotary arm drive gear 88. The driving force is transmitted to the shaft 87 by the one-way clutch 211, and the rotary arm 85 is rotated in the CW direction in FIG. 2 with the shaft 87 as a fulcrum, and as shown in FIG. A space is provided between the rollers 760 and 761 by separating the driven roller 761.
[0055]
Next, the process proceeds to step 5, and in step 5, the yarn dropping air is intermittently blown from the yarn dropping air nozzle 100 for a predetermined period as shown in FIGS. 2 (a) and 4 (a). The lower thread is surely hung downward from the lower thread derivation part of the case 2X (the lower thread derivation part of the lower thread tension spring), and the process proceeds to Step 6. In Step 6, thread guide air is then blown from the air nozzle 151 ( 2B and FIG. 4B), the lower thread end M hanging from the bobbin case 2X is blown to the working position.
[0056]
Next, the process proceeds to step 7, where the remaining yarn winding motor 86 is driven in the CW direction in FIG. 2 to rotate the drive roller 760 in the same direction (lower yarn discharging rotation direction P; see FIG. 2B). . Then, the rotational driving force whose rotational direction is reversed by the rotational arm drive gear 88 is interrupted with respect to the shaft 87 by the one-way clutch 211, and the rotational arm 85 becomes free in the CCW direction in FIG. At this time, the rotating arm 85 rotates in the CCW direction in FIG. 2 with the shaft 87 as a fulcrum by the urging force of the torsion coil spring 210 (see FIG. 2B).
[0057]
Next, the process proceeds to step 8, where the driven roller 761 faces the drive roller 760, but before the lower thread end M is sandwiched between the rollers 760 and 761, the blowing of air by the air nozzle 151 is stopped. (See FIG. 4 (b)).
[0058]
Here, when air is blown by the air nozzle 151 when the lower thread end M is sandwiched between the rollers 760 and 761, the air that passes between the rollers 760 and 761 and flows downstream is transferred to the rollers 760 and 761. The lower thread end M is blown to the working position by the air nozzle 151 as in this embodiment, although the lower thread end M escapes from between the rollers 760 and 761 and is not entrapped and discharged by the rollers 760 and 761. If the air of the air nozzle 151 is shut off as shown in FIG. 4 before the part M is sandwiched between the rollers 760 and 761 by the movement of the roller 761, the lower thread end M that has been blown up rotates. The driven roller 761 hangs on the outer peripheral surface of the driven roller 761 and the driven roller 761 is rotated by the torsional force of the coil spring 210 to rotate the roller 7. When facing the pressed state with respect to 0, a state in which the lower thread end M is sandwiched between the rollers 760 and 761 (step 9).
[0059]
In step 9, since the driving roller 760 is rotating in the CW direction, the lower thread sandwiched between the rollers 760 and 761 is wound around the rollers 760 and 761 by the co-rotation of both rollers 760 and 761. However, it is discharged downstream (see FIG. 2C).
[0060]
Then, the process proceeds to Step 10, where it is determined whether or not the remaining yarn removal of the bobbin 7 is performed. This is because the bobbin 7 is rotated and discharged when the remaining yarn is discharged downstream while the rollers 760 and 761 are cooperating with the rollers 760 and 761 (remaining yarn is removed). If there is no (remaining yarn removal is not performed), it is determined from the bobbin 7 not rotating. The presence or absence of this rotation is determined by the output signal from the reflection type optical sensor 500 described above.
[0061]
When it is determined that the bobbin 7 is not rotating, that is, the remaining yarn removal is not performed, the process returns to step 4 to retry, and the above operation is repeated. When this retry operation is performed three times in succession, in this embodiment, an alarm is generated to notify the operator of an abnormality, assuming that some failure that cannot remove the remaining yarn has occurred.
[0062]
If it is determined in step 10 that the bobbin 7 is rotating, that is, the remaining yarn removal is being performed, the process proceeds to step 11, and in step 11, it is determined whether or not the bobbin 7 has stopped this time. If it is determined that the bobbin 7 is not stopped and the remaining yarn removal is still continued, the same determination is repeated until the bobbin 7 stops, while the bobbin 7 is stopped and the remaining yarn removal is completed. If so, the process proceeds to step 12. In step 12, the remaining yarn winding motor 86 is stopped and the driving roller 760 is stopped to end this flow.
[0063]
When the remaining yarn is removed in this way, the rotating arm 70 is rotated to move the bobbin case 2X accommodating the empty bobbin to the lower thread winding position C and then advanced to move the lower thread winding position C. The lower thread winding device 162 winds the lower thread around the empty bobbin, performs threading and thread trimming, then retracts the rotating arm 70 and rotates to grip the bobbin case. The bobbin case gripping means that is not present is opposed to the hook 1 and waits until a bobbin replacement command is issued. Thereafter, these operations are repeated.
[0064]
Thus, in this embodiment, the lower thread end M hanging from the bobbin case 2 in which the bobbin 7 is housed is entrapped and discharged by the rollers 760 and 761, and the remaining thread discharge amount is not limited. Therefore, it is possible to automatically remove all bobbin remaining yarn. Further, the rollers 760 and 761 entrain and discharge the yarn end, so that the rollers 760 and 761 have the function of guiding the yarn end, and the rollers 760 and 761 having the function of guiding the yarn end are also connected to the bobbin case 2. Therefore, the remaining yarn can be reliably caught and removed. Further, there is no complicated part such as an elastic linear body as in the apparatus described in JP-A-7-68071, and the number of parts is reduced, so that the cost can be reduced.
[0065]
Further, before the lower thread end M blown to the working position by the air nozzle 151 is sandwiched between the rollers 760 and 761 by the movement of the driven roller 761, the air of the air nozzle 151 is shut off, and the lower thread end M is Since the rollers 760 and 761 are preferably wound and discharged, the remaining yarn can be reliably captured and removed.
[0066]
Further, even if the bobbin thread derived from the bobbin case 2 has been attached to the bobbin case 2, air is blown toward the bobbin case 2 bobbin case 2 by the air dripping air nozzle 100. Since the yarn is released from adhering by the air and the yarn is surely hung downward, the remaining yarn can be reliably removed by the remaining yarn removing operation thereafter.
[0067]
Particularly in this embodiment, the driving roller 760 is rotated by the remaining yarn winding motor 86 in the direction opposite to the lower yarn discharging rotation direction P, and the one-way clutch 211 is used to support the driven roller 761 from the remaining yarn winding motor 86. A driving force is transmitted to the arm 85, the rotating arm 85 is rotated in a direction in which the driven roller 761 is separated from the driving roller 760 with the shaft 87 as a fulcrum, and the lower thread is introduced between the rollers 760 and 761. , The lower thread hanging from the bobbin 7 enters between the spaces, and conversely, the driving roller 760 is rotated in the lower thread discharge rotation direction P by the remaining thread winding motor 86, and the one-way clutch 211 The remaining yarn winding motor 86 cuts off the driving force with respect to the rotary arm 85, and at this time, the rotational force is applied by the urging force of the torsion coil spring 210. The roller 85 is rotated about the shaft 87 so that the driven roller 761 is directed toward the driving roller 760, and the driven roller 761 is pressed against the driving roller 760, and the lower thread is sandwiched between the two rollers 760 and 761. Thus, the bobbin residual yarn is wound and discharged by the cooperation of both rollers 760 and 761, and a residual yarn winding motor as one driving means is provided without separately providing a driving means for the driving roller and a driving means for the rotary arm 85. Since both are driven at 86 and the number of parts (motor, bracket, shaft, gear, etc.) is reduced and a free space is generated as compared with the case where drive means are provided separately, the cost is low. It is possible to improve the degree of freedom of design as well as the design.
[0068]
If the driving means for the driving roller and the driving means for the rotating arm 85 are separately provided, the driving means for the rotating arm 85 must be excited when the rollers 760 and 761 are pressed against each other. In this case, since this is not the case, it is possible to improve the reliability related to the durability as compared with the case where the driving means is provided separately.
[0069]
FIG. 7 shows the main part of the residual yarn removing device in the second embodiment of the present invention, (a) is a front view showing the initial state of the residual yarn winding motor and the state during CW rotation, ) Is a front view showing the state of the remaining yarn winding motor during CCW rotation, and the same components as those in the first embodiment are denoted by the same reference numerals.
[0070]
In the remaining yarn removing device of the second embodiment, the rotary arm transmission gear 91, the rotary arm drive gear 88, and the one-way clutch 211 in the first embodiment are eliminated. That is, the shaft 87 to which the rotary arm 85 is fixed is urged in the CCW direction in FIG. 7 by the torsion coil spring 210 in a state where the shaft 87 is rotatably spanned on both side plates 80a and 80b of the bracket 80. It has become.
[0071]
A one-way clutch 211a is provided on the outer periphery of the shaft portion between both side plates 80a and 80b of the bracket 80 on the rotating shaft 79, and a cam 220 having a substantially sectional fan shape is fixed to the outer periphery of the one-way clutch 211a. . The one-way clutch 211 a is locked when a rotational driving force in the counterclockwise direction (CCW direction) in FIG. 7 is applied from the rotating shaft 79, while transmitting the driving force in the rotating direction to the cam 220, while the rotating shaft 79. 7 is applied, the locked state is released when the rotational driving force in the clockwise direction (CW direction) in FIG. 7 is applied, and the driving force in the rotational direction is freed from the cam 220. . Reference numeral 221 denotes a stopper, and the other configuration is the same as that of the first embodiment, and therefore the description thereof is omitted here to avoid duplication.
[0072]
Therefore, in the initial state, the rotary arm 85 is in the position shown in FIG. 7A, that is, the position where the driving roller 760 and the driven roller 761 come into contact with each other, and the end of the side plate 85a of the rotary arm 85. The cam 220 is in a position where it comes into contact with the protrusion 220a.
[0073]
When the remaining yarn winding motor 86 is driven in the CCW direction in FIG. 7 and the driving roller 760 is rotated in the same direction, this rotational driving force is transmitted to the cam 220 by the one-way clutch 211a, and the cam 220 uses the shaft 79 as a fulcrum. By rotating in the CCW direction and this driving force (pressing force) is transmitted to the rotating arm 85 by the tip portion 220a of the cam 220, the rotating arm 85 rotates in the CW direction in FIG. As shown in FIG. 7B, the driven roller 761 is separated from the driving roller 760 so that a space is generated between the two rollers 760 and 761.
[0074]
Further, when the remaining yarn winding motor 86 is driven in the CW direction in FIG. 7 and the driving roller 760 is rotated in the same direction (lower yarn discharging rotation direction P; see FIG. 2B), this rotational driving force is generated by the one-way clutch 211a. , And the cam 220 becomes free in the CCW direction in FIG. 7. At this time, the rotary arm 85 uses the urging force of the torsion coil spring 210 as a fulcrum to support the shaft 87 in the CCW direction in FIG. 7. The driven roller 761 is pressed against the driving roller 760 by this urging force (see FIG. 7A).
[0075]
That is, it is configured to be able to perform the same operation as in the first embodiment, and it is needless to say that the same effect as in the first embodiment can be obtained.
[0076]
In addition, in the second embodiment, the driving force is transmitted to the rotating arm 85 by the one-way clutch 211a via the cam 220, and the rotating arm 85 is opened when the driven roller 761 is separated from the driving roller 760. Since the angle can be set according to the shape of the cam 220, the above-described effects can be further enhanced by further increasing the degree of freedom in design.
[0077]
Further, as compared with the first embodiment, the rotary arm transmission gear 91 and the rotary arm drive gear 88 can be eliminated, and the above-described effects can be further enhanced by further reducing the cost. Yes.
[0078]
FIG. 8 shows the main part of the residual yarn removing device according to the third embodiment of the present invention. FIG. 8A is a front view showing the initial state of the residual yarn winding motor and the state during CW rotation. ) Is a front view showing the state of the remaining yarn winding motor during CCW rotation. The same reference numerals are given to the same components as those in the second embodiment, and the description here is made to avoid duplication. Is omitted.
[0079]
The remaining yarn removing device of the third embodiment is different from that of the second embodiment in that a cam 225 is used in place of the cam 220, and the driven roller 761 is driven with respect to the driving roller 760 according to the shape of the cam 225. The opening angle of the rotating arm 85 at the time of separation is larger than that of the cam 220 described above.
[0080]
Needless to say, even if configured in this way, the same effects as those of the second embodiment can be obtained.
[0081]
FIG. 9 is a right side view of a bobbin thread automatic supply device to which the residual yarn removing device according to the fourth embodiment of the present invention is applied. In the residual yarn removing apparatus of the fourth embodiment, the rotary arm 85 is fixed and penetrates the base plate 3 and is coaxial with the shaft 87 rotatably spanned on both side plates 80a and 80b of the residual yarn bracket 80. From above, the cup-shaped friction clutch plate 250b, the clutch pressure contact spring 250c, and the open end toward the front side from the left side to the right side of the rotary arm 85 from the left side to the right side in the drawing. A cup-shaped storage portion 250a, and a rotary arm drive gear 88 with the storage portion 250a fixed to the end thereof are sequentially arranged. The friction clutch plate 250b, the clutch pressure contact spring 250c, the storage portion 250a, and the rotary arm drive gear 88. The shaft is penetrated by the shaft 87 and is rotatably supported on the shaft 87. The clutch pressure contact spring 250c is accommodated between the friction clutch plate 250b and the accommodating portion 250a, and is arranged in the clutch pressure contact spring 250c by a plurality of pins (not shown) fixed between the friction clutch plate 250b and the accommodating portion 250a. The friction clutch plate 250b and the rotation in the storage portion 250a are in a restricted state.
[0082]
That is, the side plate 85b on the back side of the rotary arm 85 and the friction clutch plate 250b are in a pressure contact state due to the pressure contact force of the clutch pressure contact spring 250c, and the rotation drive force of the rotation arm drive gear 88 is the accommodation portion 250a and the clutch pressure contact spring 250c. Friction is transmitted to the rotary arm 85 via the friction clutch plate 250b, and the rotary arm 85 can be rotated about the shaft 87 as a fulcrum. Here, the driving force transmission means 250 is comprised by the friction clutch board 250b, the clutch press-contact spring 250c, and the accommodating part 250a. Since other configurations are the same as those of the first embodiment, the description thereof is omitted to avoid duplication.
[0083]
Therefore, in the initial state, the rotary arm 85 is in the same position as in the first embodiment, that is, the position where the driving roller 760 and the driven roller 761 come into contact.
[0084]
When the remaining yarn winding motor 86 is driven in the CCW direction and the driving roller 760 is rotated in the same direction as in the first embodiment, the rotational driving force is reversed in the rotational direction by the rotating arm driving gear 88. The rotational driving force thus transmitted is frictionally transmitted to the rotary arm 85 via the storage portion 250a, the clutch pressure contact spring 250c, and the friction clutch plate 250b, and the rotary arm 85 rotates in the CW direction with the shaft 87 as a fulcrum, thereby driving roller 760. On the other hand, the driven roller 761 is separated so that a space is formed between the two rollers 760 and 761.
[0085]
Further, when the remaining yarn winding motor 86 is driven in the CW direction and the driving roller 760 is rotated in the same direction (lower yarn discharging rotational direction P; see FIG. 2B), this rotational driving force is caused by the rotary arm driving gear 88. The rotation direction is reversed, and the reversed rotational driving force is frictionally transmitted to the rotation arm 85 via the storage portion 250a, the clutch pressure contact spring 250c, and the friction clutch plate 250b. The rotation arm 85 is CCW direction with the shaft 87 as a fulcrum. The driven roller 761 is pressed against the driving roller 760.
[0086]
Thus, when the driven roller 761 is pressed against the driving roller 760, the rotation in the CCW direction with the shaft 87 of the rotating arm 85 as a fulcrum becomes impossible, and the friction clutch plate 250b and the rotating arm Slip occurs between the inner plate 85 and the side plate 85b on the back side of the roller 85, and no further pressing force is applied (the pressing force is maintained), and the driving roller 760 continues to rotate in the CW direction. Accordingly, the lower thread sandwiched between the rollers 760 and 761 is discharged downstream while being wound around the rollers 760 and 761 by the cooperative rotation of both rollers 760 and 761.
[0087]
That is, it is configured to be able to perform the same operation as in the first embodiment, and it is needless to say that the same effect as in the first embodiment can be obtained.
[0088]
Although the invention made by the present inventor has been specifically described based on the embodiments, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the invention. Needless to say, for example, in the above embodiment, one roller is used as a driving roller and the other roller is used as a driven roller.
[0089]
The rollers 760 and 761 may be rubber rollers or toothed rollers.
[0090]
Moreover, in the said Example, although air is intermittently sprayed with the air nozzle 100 for thread dropping, of course, it is good also as continuous spraying. Further, although the yarn dropping air nozzle 100 is provided so as to be sprayable toward the yarn lead-out portion of the bobbin case 2, instead of this, a plurality of yarn dropping air is equally distributed toward the bobbin case central portion. Even if a nozzle is provided and a predetermined air flow is generated toward the bobbin case 2, the same effect can be obtained.
[0091]
【The invention's effect】
As described above, according to the bobbin residual yarn removing device of claim 1, roller Is rotated in the direction opposite to the lower thread discharge rotation direction by the drive means, and a pair of drive force transmission means from the drive means roller A driving force is transmitted to the rotating arm that supports the rotating arm, and the rotating arm is connected to the pair of arms with one axis serving as a fulcrum. roller Rotate in the direction of separating roller A space for introducing the lower thread is secured between the bobbins and the bobbin droops from the bobbin between these spaces. edge On the contrary, the above pair of roller Is rotated in the lower thread discharge rotation direction by the driving means, and the driving force is cut off from the driving means to the rotating arm by the driving force transmitting means. roller Rotate so that roller The lower thread between the rotating bodies edge The bobbin remaining yarn is entangled and discharged by the co-operation of both rotating bodies, and this bobbin discharge amount is not limited, so it is possible to automatically remove all bobbin remaining yarn It becomes.
Also, roller Entangles and discharges the yarn end, roller In addition, it has the function of thread end guidance, and also has the function of thread end guidance. roller Is configured to be close to the yarn end outlet of the bobbin case, so that the remaining yarn can be reliably removed.
Also, since there are no complicated parts such as elastic linear bodies and the number of parts is reduced, the cost can be reduced.
Furthermore, one side roller The drive means for the arm and the drive means for the rotating arm are not provided separately, but both are driven by a single drive means, and the number of parts is reduced and an empty space compared to the case where the drive means are provided separately. Therefore, it is possible to reduce the cost and improve the degree of freedom of design.
According to the bobbin residual yarn removing device of claim 2, roller Is rotated in the direction opposite to the lower thread discharge rotation direction by the driving means, and a pair of driving force transmission / cutoff means roller A driving force is transmitted to the rotating arm that supports the rotating arm, and the rotating arm is connected to the pair of arms with one axis serving as a fulcrum. roller Rotate in the direction of separating roller A space for introducing the lower thread is secured between the bobbins and the bobbin droops from the bobbin between these spaces. edge On the contrary, on the contrary, roller Is rotated in the lower thread discharge rotation direction by the driving means, and the driving force is cut off from the driving means to the rotating arm by the driving force transmitting / cutting means. At this time, the rotating arm is moved by the urging force of the urging means. , A pair of the above about one axis roller Rotate so that roller As the state of pressing both roller Between lower thread edge Hold both ends of the bobbin roller The bobbin remaining yarn can be automatically removed automatically because the remaining yarn discharge amount is not limited.
Also, roller Entangles and discharges the yarn end, roller In addition, it has the function of thread end guidance, and also has the function of thread end guidance. roller Is configured to be close to the yarn end outlet of the bobbin case, so that the remaining yarn can be reliably removed.
Also, since there are no complicated parts such as elastic linear bodies and the number of parts is reduced, the cost can be reduced.
Furthermore, one side roller The drive means for the arm and the drive means for the rotating arm are not provided separately, but both are driven by a single drive means, and the number of parts is reduced and an empty space compared to the case where the drive means are provided separately. Therefore, it is possible to reduce the cost and improve the degree of freedom of design.
[0092]
According to the bobbin residual yarn removing device of claim 3, in addition to claim 2, the driving force is transmitted to the rotating arm by the driving force transmitting / blocking means via the cam, roller Against the other roller Since the opening angle of the rotating arm at the time of separation is set according to the cam shape, the above-described effects can be further enhanced by increasing the degree of design freedom.
[0093]
According to the bobbin residual thread removing device of claim 4, roller Is rotated in the direction opposite to the lower thread discharge rotation direction by the drive means, and a pair of drive force transmission means from the drive means roller A driving force is transmitted to the rotating arm that supports the rotating arm, and the rotating arm is connected to the pair of arms with one axis serving as a fulcrum. roller Rotate in the direction of separating roller A space for introducing the lower thread is secured between the bobbins and the bobbin droops from the bobbin between these spaces. edge On the contrary, on the contrary, roller Is rotated in the lower thread discharge rotation direction by the driving means, and the driving force is transmitted from the driving means to the rotating arm by the driving force transmitting means. roller Rotate in the direction that the roller Between lower thread edge A pair of these roller When the is in the pressing state, the driving force is transmitted from the driving means to the rotating arm by the driving force transmitting means so as to hold the pressing force, roller Will continue to rotate in the bobbin thread discharge rotation direction without bearing, so roller The bobbin remaining yarn can be automatically removed automatically because the remaining yarn discharge amount is not limited.
Also, roller Entangles and discharges the yarn end, roller In addition, it has the function of thread end guidance, and also has the function of thread end guidance. roller Is configured to be close to the yarn end outlet of the bobbin case, so that the remaining yarn can be reliably removed.
Also, since there are no complicated parts such as elastic linear bodies and the number of parts is reduced, the cost can be reduced.
Furthermore, one side roller The drive means for the arm and the drive means for the rotating arm are not provided separately, but both are driven by a single drive means, and the number of parts is reduced and an empty space compared to the case where the drive means are provided separately. Therefore, it is possible to reduce the cost and improve the degree of freedom of design.
[Brief description of the drawings]
FIG. 1 is a right side view of a bobbin thread automatic supply device to which a residual yarn removing apparatus according to a first embodiment of the present invention is applied.
2 is a front explanatory view showing only the main part of the residual yarn removing device of FIG. 1 in order to explain the operation of the residual yarn removing device. FIG.
FIG. 3 is a flowchart showing an operation procedure of the residual yarn removing apparatus.
FIG. 4 is a timing chart for explaining the operation of the above-described residual yarn removing apparatus.
FIG. 5 is a front view of the bobbin used in the present embodiment on the rotation detection means side.
FIG. 6 is a waveform diagram detected when the bobbin rotates.
FIG. 7 shows a main part of a residual yarn removing device according to a second embodiment of the present invention, in which (a) is a front view showing an initial state of the residual yarn winding motor and a state during CW rotation; b) is a front view showing a state during CCW rotation of the remaining yarn winding motor.
FIG. 8 shows a main part of a residual yarn removing device according to a third embodiment of the present invention, in which (a) is a front view showing an initial state of a residual yarn winding motor and a state during CW rotation; b) is a front view showing a state during CCW rotation of the remaining yarn winding motor.
FIG. 9 is a right side view of a bobbin thread automatic supply device to which a residual yarn removing apparatus according to a fourth embodiment of the present invention is applied.
FIG. 10 is a front view of the bobbin thread automatic feeding device showing the arrangement relationship of the devices used in the upper and lower yarn automatic feeding device.
FIG. 11 is a front view of a bobbin exchanging device used in the upper and lower thread automatic supply device.
FIG. 12 is a plan view of the bobbin exchanging device.
FIG. 13 is a right side view showing a linear motion mechanism portion in the bobbin exchanging device.
FIG. 14 is a right side view showing a rotating mechanism portion in the bobbin exchanging device.
FIG. 15 is a schematic side view for explaining a dummy position and a dummy shaft of the bobbin exchanging device.
[Explanation of symbols]
7 Bobbins
85 Rotating arm
86 Driving means
87 uniaxial
210 Energizing means
211, 211a Driving force transmission / cutoff means
220,225 cam
250 Driving force transmission means
760 One rotating body
761 The other rotating body
M Lower thread
P Lower thread discharge rotation direction

Claims (4)

A bobbin supported rotatably;
Lower thread introduction that is arranged below the bobbin and is movable to a contact position and a separation position, and into which the lower thread end drooping from the bobbin enters by moving from the contact position to the separation position. A pair of rotatable rollers that pinch the lower thread end by moving from the separated position to the abutted position, and entangle and discharge the pinched lower thread from the end ,
One driving means for rotating one or both of the pair of rollers in a direction opposite to the lower thread discharging rotation direction or the lower thread discharging rotation direction;
When the rotational direction of the roller is lower thread discharge direction of rotation is moved to the position to contact the pair of rollers, the pair of rollers when the rotational direction of the rollers and the lower thread discharge direction of rotation are opposite to each Driving force transmitting means for transmitting the driving force of the driving means to the pair of rollers so as to be moved to a position to be separated; and
A bobbin residual yarn removing device comprising: A bobbin supported rotatably;
Lower thread introduction that is arranged below the bobbin and is movable to a contact position and a separation position, and into which the lower thread end drooping from the bobbin enters by moving from the contact position to the separation position. A pair of rotatable rollers that pinch the lower thread end by moving from the separated position to the abutted position, and entangle and discharge the pinched lower thread from the end ,
And one drive means for rotating in a direction opposite to the one roller or both rollers bobbin thread discharging rotational direction or lower thread discharging rotational direction of the pair of rollers,
A rotating arm rotatably supported around a single as well as supporting the one roller of the pair of rollers,
A biasing means for biasing the rotating arm around the one axis so that the other roller faces the one roller ;
When the roller rotates in the direction opposite to the lower thread discharge rotation direction, the drive means rotates the rotating arm in a direction in which the pair of rollers separate from each other, while the roller moves in the lower thread discharge rotation direction. during rotation, the driving force by the driving means so as the pair of rollers by rotating said rotary Doude a direction in which the pair of rollers is in contact is pressed state abuts the biasing force of the biasing means Driving force transmission / blocking means for blocking the rotating arm;
A bobbin residual yarn removing device comprising: In the bobbin residual thread removing device according to claim 2,
The bobbin residual yarn removing device, wherein the driving force is transmitted to the rotating arm by the driving force transmitting / blocking means via a cam. A bobbin supported rotatably;
Lower thread introduction that is arranged below the bobbin and is movable to a contact position and a separation position, and into which the lower thread end drooping from the bobbin enters by moving from the contact position to the separation position. A pair of rotatable rollers that pinch the lower thread end by moving from the separated position to the abutted position, and entangle and discharge the pinched lower thread from the end ,
And one drive means for rotating in a direction opposite to the one roller or both rollers bobbin thread discharging rotational direction or lower thread discharging rotational direction of the pair of rollers,
A rotating arm rotatably supported around a single as well as supporting the one roller of the pair of rollers,
When the roller rotates in the direction opposite to the lower thread discharge rotation direction, the drive means rotates the rotating arm in a direction in which the pair of rollers separate from each other, while the roller lower thread discharge rotation direction. upon rotation, driven by the driving means so that said pair of rollers to hold the the and rotate the said rotary Doude in abutting direction thereof a pair of rollers the pressing state abuts the pressing force of the rotation arm Driving force transmitting means for transmitting force to the rotating arm;
A bobbin residual yarn removing device comprising:

Images