The present application claims priority from Japanese Patent Application No. 2006-308878 filed on Nov. 15, 2006, the entire content of which is incorporated herein by reference.
The present invention relates to a sewing machine having a threading device for inserting a lower thread into a thread hole of a looper.
There is a threading device in which compressed air is sprayed onto a thread inserting port of a thread pipe, guiding a lower thread toward a thread hole of a looper, to insert the lower thread into the thread hole of the looper through the thread pipe by an air flow (see, e.g., Japanese Patent No, 2865470).
When the looper, which swivels back and forth, is at a front position, an upper thread is usually being caught by the looper. When inserting the lower thread into the thread hole of the looper in this state, it is cumbersome to pull away the upper thread passing through the looper or to consider the order of threading.
In a looper mechanism disclosed in the Japanese Patent No. 2865470, moreover, the looper is swiveled interlockingly with a rotation of a main shaft (a lower shaft) which serves as a driving shaft. Thus, in order to prevent the threading work from being hindered by a movement of the looper, it is necessary to stop and keep the looper at a predetermined position when inserting the lower thread into the looper.
Accordingly, as shown in
It is an object of the present invention to facilitate a threading work to insert a thread into a looper.
According to an aspect of the invention, a sewing machine includes a looper having an extended portion. A thread hole is formed on a tip portion of the extended portion, and a looper groove is formed along the extended portion. The sewing machine further includes a looper shaft holding the looper such that the looper is swivelable between a front position and a rear position in synchronization with a vertical motion of a needle and interlockingly with a motor, and a thread pipe fixed to the looper shaft such that the thread pipe is swivelable between a front position and a rear position. A thread inserting port at one end of the thread pipe and a thread discharging port at the other end of the thread pipe is communicated such that a thread can be inserted therethrough. The sewing machine further includes air supplying means for supplying air toward the thread inserting port when a nozzle is disposed at a spraying position opposed to the thread inserting port of the thread pipe, switching means for disconnecting the looper from the looper shaft when the looper is at the front position, and moving means for moving the looper, which is disconnected from the looper shaft by the switching means, to the rear position. When the looper is disconnected from the looper shaft and is moved to the rear position, the thread discharging port of the thread pipe becomes coincident with the thread hole of the looper which is moved to the rear position, and the thread inserting port of the thread pipe becomes coincident with a tip of the nozzle disposed at the spraying position.
The sewing machine may further include a looper support member supporting the looper and is rotatable with respect to the looper shaft, a looper driving member fixed to the looper shaft, and a coupling member which is movable along an axial direction of the looper shaft. The coupling member may be operable to connect or disconnect the looper support member and the looper driving member when the coupling member is moved while the looper and the thread pipe are disposed at the respective rear positions.
The sewing machine may further include a main shaft locking mechanism which positions a main shaft at a predetermined rotating angle at which the thread pipe is disposed at the front position through the looper shaft, and operation input means for moving the nozzle to the spraying position, bringing the switching means into a disconnecting state, and bringing the main shaft locking mechanism into an operable state.
The air supplying means may allow the nozzle to move between the spraying position and a standby position placed apart from the spraying position. The air supplying means may include nozzle biasing means for biasing the nozzle toward the spraying position. A position of the operation input means may be switchable between a holding position at which the nozzle is held at the standby position against a biasing force of the nozzle biasing means and a permitting position at which the nozzle biasing means is movable to the spraying position by the biasing force.
The sewing machine may further include detecting means for detecting that the main shaft is positioned at the predetermined rotating angle by the main shaft locking mechanism, and motor control means for starting of a rotation of the motor when the main shaft locking mechanism is brought into the operable state in accordance with an input operation from the operation input means and stopping the rotation of the motor when the main shaft is positioned at the predetermined rotating angle.
The main shaft locking mechanism may include a rotating member having an engaging portion and fixed to the main shaft, a lock member which positions the main shaft at the predetermined rotating angle when engaged with the engaging portion, and lock member biasing means for biasing the lock member in a direction in which the lock member engages with the engaging portion.
The engaging portion may be an opening portion formed on the rotating member, and the lock member may engage with the opening portion of the rotating member in an axial direction of the main shaft.
The lock member may engage with the opening portion of the rotating member in a radial direction of the main shaft.
The main shaft locking mechanism may further includes a link member which rotates in accordance with an input operation from the operation input means. The lock member and the link member may share a same rotating axis and are separately rotatable. The lock member biasing means may include a tension spring coupling the link member and the lock member.
The sewing machine may further include an operating member which is movable when operated from an outside of the sewing machine, and a main shaft locking mechanism which positions a main shaft at a predetermined rotating angle, at which the thread pipe is movable to the front position, interlockingly with the movement of the operating member. The switching means may include a switching member coupled to the looper and supported by the looper shaft so as to be movable along an axial direction of the looper shaft such that the switching member disconnects the looper from the looper shaft interlockingly with the movement of the operating member when the looper is disposed at the front position. The moving means may include an acting member which moves the looper to the rear position when the switching member is moved to disconnect the looper from the looper shaft.
The sewing machine may further include an operating member which is movable when operated from an outside of the sewing machine, and a main shaft locking mechanism which positions a main shaft at a predetermined rotating angle, at which the thread pipe is movable to the front position, interlockingly with the movement of the operating member. The air supplying means may be operable to move the nozzle between to the spraying position and a standby position placed apart from the spraying position. The operating member may be coupled to the nozzle such that, when the operating member is moved, the looper is disposed at the rear position and the nozzle is moved to the spraying position.
Other aspects and advantages of the invention will be apparent from the following description, the drawings and the claims.
Hereinafter, exemplary embodiments of the invention will be explained with reference to the drawings, the following exemplary embodiments do not limit the scope of the invention. In the following exemplary embodiments, description will be given by taking a double chainstitch sewing machine as an example of a sewing machine. The double chainstitch sewing machine includes needles 4 which move in a vertical direction and a looper 21 (a double chain looper) which inserts a looper thread T through loops of sewing threads (i.e., needle threads or upper threads), which is inserted through the needles 4, below a cloth (a workpiece). The double chainstitch sewing machine sequentially crosses the threads by the needles 4 and the looper 21, and forms a double chainstitches on the cloth.
In the following description, a Z-axis direction is the vertical direction (an up-and-down direction), a Y-axis direction (a right-and-left direction) is a longitudinal direction of an arm portion 2a of a sewing machine 1 in a state in which the sewing machine 1 is placed on a horizontal plane, and an X-axis direction (a front-and-rear direction) is a direction parallel to a surface of a throat plate (not shown) and orthogonal to the Y-axis direction. The X-axis direction, the Y-axis direction and the Z-axis direction are orthogonal to each other.
As shown in
Needle Driving Mechanism
The needle driving mechanism (not shown) includes an upper shaft (not shown) which is rotated by the motor 5, and a vertical motion transmitting mechanism which converts a rotating motion of the upper shaft into a vertical reciprocating motion through a rotating weight and a crank rod and transmits the vertical reciprocating motion to a needled bar 3. Two needles 4 are held on a lower end of the needle bar 3. When the upper shaft is rotated by a driving operation of the motor 5, the vertical motion is given to the needle bar 3 through the vertical motion transmitting mechanism so that the needle bar 3 and the needle 4 carry out the vertical reciprocating motion.
Looper Driving Mechanism
The looper driving mechanism 20 is arranged below a throat plate (not shown). The looper driving mechanism 20 includes a looper driving shaft 22 which is rotatably supported on a frame 2 along the X-axis direction, a rotation transmitting mechanism (not shown) which is branched from a lower shaft 6 (a main shaft) and converts a rotating force of the lower shaft 6 into a rotational reciprocating force to transmit the rotational reciprocating force to the looper driving shaft 22 (see
The rotational reciprocating force is applied to the looper driving shaft 22 from the lower shaft 6 via the rotation transmitting mechanism (not shown), whereby the looper driving shaft 22 carries out a reciprocating rotation in synchronization with the rotation of the lower shaft 6. The looper driving shaft 22 functions as a looper shaft which swivels the looper 21 and a thread pipe 110 between front positions and rear positions, respectively.
The looper driving arm 24 is fixed to the looper driving shaft 22 and is swiveled in accordance with the rotation of the looper driving shaft 22. The looper driving arm 24 is formed with a slot 24a on a left side of a coupling portion to the looper driving shaft 22 when seen in a direction D shown in
The looper support arm 23 is rotatably fitted in the looper driving shaft 22 so as to be juxtaposed with the looper driving arm 24. The looper support arm 23 is formed with a slot 23a at a position corresponding to the slot 24a of the looper driving arm 24, i.e., on a left side of a coupling portion to the looper driving shaft 22 when seen in a direction D shown in
The looper 21 includes an extended portion 21a which can be inserted into the loops of the needle threads by moving back and forth in synchronization with the vertical motion of the needles 4. As shown in
A flywheel 7 is attached to one end of the lower shaft 6 extended to an outside of the frame 2. The flywheel 7 and the lower shaft 6 are coupled so to be rotatable together. An indicator m1 is provided on an edge portion of the flywheel 7, and an indicator m2 is provided on an edge portion of the frame 2 near the indicator m1 (see
Threading Device
Next, description will be given to the threading device 100 according to the first exemplary embodiment.
The threading device 100 is for inserting the looper thread T, which is guided along a thread groove 8 formed on the frame 2, through the thread hole 21b of the looper 21, and is provided inside a bed portion 2b shown in
As shown in
Thread Guiding Means
As shown in
The thread pipe 110 is fixed to a side surface of the thread guide plate 113 which is fixed to the looper driving arm 24. When the looper support arm 23 is coupled to the looper driving arm 24, the thread pipe 110 is swiveled together with the looper 21 and interlockingly with the looper driving shaft 22, and is reciprocated between the front position shown in
Air Supplying Means
The air spraying unit 120 includes the air nozzle 121, an air pump 130, and an air spray moving mechanism 140. The air nozzle 121 sprays air toward the thread inserting port 111 into the thread pipe 110, and generates an air flow inside the thread pipe 110. The air pump 130 supplies the air to the air nozzle 121. The air spray moving mechanism 140 moves the air spraying unit 120 in order to move the air nozzle 121 between the spraying position P1 (see
As shown in
The air pump 130 includes an extensible and hollow bellows portion 131, and a lever portion 132 connected to one end of the bellows portion 131 and operable to compress the bellows portion 131. The other end of the bellows portion 131 is connected to the air nozzle 121 through an air tube 133. Namely, in the air pump 130, the lever portion 132 is operated to compress the bellows portion 131 so that the air inside the bellows portion 131 is sent to the air nozzle 121 through the air tube 133, whereby the air is discharged from the air outlet 121a at the tip of the air nozzle 121.
As shown in
One end of the operating plate base 141 is fixed to a bottom surface in the bed portion 2b with a screw, and the other end is bent upward at almost 90 degrees so as to be in parallel to a Y-Z plane. The operating plate base 141 has two projections 141a which are protruded in the X-axis direction and are arranged along the Y-axis direction. Each of the projections 141a is engaged with respective slots 142b of the operating plate 142, whereby the air spraying unit 120 is slidably supported in the Y-axis direction.
The air nozzle 121 is attached to the operating plate 142 along its moving direction, i.e., the Y-axis direction. The operating plate 142 includes a bent portion 142a at its lower end which is bent toward an inner side of the sewing machine 1 and is extended in the X-axis direction, and an operation lever 142c which moves the air spraying unit 120 in accordance with a manual operation of the operator. The operating plate 142 is formed with the two slots 142b extending along the Y-axis direction, and a slit 142d which allows the lock button 144 to switch the moving and the stopping of the operating plate 142.
One end of a release link 172 of the interlocking mechanism 170 is rotatably coupled to a tip portion of the bent portion 142a (see
The slots 142b are engaged with the respective projections 141a of the operating plate base 141 such that the operating plate 142 is slidable in the Y-axis direction, and such that the air nozzle 121 supported on the operating plate 142 is movable between the spraying position P1 and the standby position P2.
The operation lever 142c is bent in the X-axis direction at an upper end of the operating plate 142 and is extended toward a front side of the sewing machine 1, i.e., toward a side of an operating position of the operator. The operation lever 142c is engaged with a lever groove 9 formed on the frame 2 so as to be movable in the Y-axis direction. By manipulating the operation lever 142c, the operator can move the air spraying unit 120 in the Y-axis direction.
The slit 142d includes a holding portion 142da and a permitting portion 142db having a smaller diameter than the holding portion 142da. When a large diameter portion 144b of the lock button 144 is inserted into the holding portion 142da, the air nozzle 121 supported on the operating plate 142 is held at the standby position P2 against a biasing force of the spring 143. The permitting portion 142db has a smaller width than the holding portion 142da allows only a small diameter portion 144a of the lock button 144 to move in the Y-axis direction therethrough, thereby permitting the movement of the air nozzle 121 supported on the operating plate 142 toward the spraying position P1. The holding portion 142da of the slit 142d is provided on a side of an end the permitting portion 142db at the spraying position P1 side (a left end in
One end in the Y-axis direction of the operating plate 142 is bent almost perpendicularly along the X-axis direction toward a side of the lower shaft 6, and holds a lock shaft 162 of the main shaft locking mechanism 160. This lock shaft 162 and the lock button 144 (operation input means) restricts a movement of the operating plate 142 in the X-axis and Z-axis directions. Thus, the operating plate 142 is movable only in the Y-axis direction.
One end of the spring 143 is coupled to one end of the operating plate 142 (a left end in
The lock button 144 is a rod-shaped member disposed such that a longitudinal direction thereof is arranged along the X-axis direction. As shown in
A flange portion 144c is provided at a central part in the longitudinal direction of the lock button 144, and a coil spring 146 (a compression spring) is provided between the flange portion 144c and the frame 2. Namely, the lock button 144 is constantly biased toward the front side of the sewing machine 1 by an elastic force of the coil spring 146. When the large diameter portion 144b is inserted into the holding portion 142da, the flange portion 144c is held in an engaging state against an end face of the operating plate 142. On the other hand, when the lock button 144 is pushed toward the side of the frame 2 against the biasing force of the coil spring 146 by the operation of the operator, the small diameter portion 144a of the lock button 144 becomes movable along the permitting portion 142db of the slit 142d. As a result, the air nozzle 121 supported on the operating plate 142 is moved toward the spraying position P1 by the biasing force of the spring 143. When the small diameter portion 144a is engaged with the permitting portion 142db of the slit 142d, the large diameter portion 144b is engaged with the end face of the operating plate 142.
Switching Mechanism
The switching mechanism 150 is for disconnecting (separating) the looper 21 from the looper shaft 22 when the looper 21 and the thread pipe 110 are at their front positions. As shown in
As shown in
A projection 173b of a release driving arm 173 of the interlocking mechanism 170 is engaged between the flange portions 151a and 151b from below. The projection 173b is movable in the X-axis direction so as to be able to abut against a lower portion of an end face of the flange portion 151. The flange portion 151b functions as a power transmitting portion which transmits a moving force in a direction C′ to the release slide base 151 from the projection 173b of the interlocking mechanism 170. The projection 173b is moved in the X-axis direction (directions C-C′) in accordance with an operation of the interlocking mechanism 170. A gap between the flange portions 15la and 151b may be provided such that the projection 173b abuts against the end face of the flange portion 151b only when the projection 173b moves in the direction C′ and such that the projection 173b separates from the end face of the flange portion 151b when the projection 173b moves in the direction C.
The release pin 152 (the switching member) is provided in the vicinity of the edge of the flange portion 151a on a left side in a horizontal direction from the looper driving shaft 22 when seen in the direction D shown in
One end (an upper end) of the spring 153 (an acting member) is coupled to an edge portion of the flange portion 151a on the opposite side of the release pin 152 interposing the looper driving shaft 22 therebetween. The other end (a lower end) of the spring 153 is coupled to the inner bottom surface of the bed portion 2b of the frame 2. The spring 153 is a tension spring, and constantly biases the release slide base 151 around the looper driving shaft 22 in one rotating direction, i.e., a rearward moving direction of the looper 21 (a direction A shown in
The coil spring 154 is provided on the opposite side of the looper support arm 23 interposing the release slide base 151 therebetween. The coil spring 154 is fitted around the outer surface of the looper driving shaft 22. One end of the coil spring 154 is engaged with the end face of the flange portion 151b and the other end is engaged with an end face of a flange 22a fixed to the looper driving shaft 22. Namely, the coil spring 154 constantly biases the release slide base 151 toward the looper support shaft 23 (in the direction C shown in
When the release slide base 151 is disposed on a side of the direction C, i.e., a side of the looper support arm 23 so that the release pin 152 is inserted into the slot 24a of the looper driving arm 24 (see
Main Shaft Locking Mechanism
As shown in
The main shaft lock plate 161 is rotated together with the lower shaft 6 by the driving operation of the motor 5. The engaging portion 161a is formed on a peripheral edge of the main shaft lock plate 161 such that the main shaft lock plate 161 is partially cut away.
The lock shaft 162 has a shape of a round bar. One end of the lock shaft is attached to one end of the operating plate 142 of the air spray moving mechanism 140. The lock shaft 162 is provided in parallel to the lower shaft 6, i.e., in the Y-axis direction. The other end of the lack shaft 162 penetrates the frame 2 from an outer side to an inner side thereof in the Y-axis direction, and is movable along its axial direction. The lock shaft 162 is moved in the Y-axis direction together with the operating plate 142 in accordance with the movement of the operating plate 142 in the Y-axis direction.
In the first exemplary embodiment, when the indicator m2 on an external surface of the frame 2 matches the indicator m1 of the flywheel 7, the lock shaft 162 can be fitted, in the axial direction, into the engaging portion 161a which opened in a groove shape by partially cutting away the main shaft lock plate 161. In other words, according to the main shaft locking mechanism 160 of the first exemplary embodiment, the lower shaft 6 is stopped (locked) by the lock shaft 162 at a rotating angle at which the looper 21, interlocking with the lower shaft 6, is at a foremost moving position in the back and forth movement (see
Interlocking Mechanism
The interlocking mechanism 170 of the sewing machine 1 according to the first exemplary embodiment will be described in detail with reference to the drawings.
The interlocking mechanism 170 includes the release driving arm 173 which moves the release slide base 151 of the switching mechanism 150 in the X-axis direction, a release link base 171 supporting the release driving arm 173 rotatably in a horizontal direction, and the release link 172 coupling the operating plate 142 of the air spray moving mechanism 140 and the release driving arm 173 (see
As shown in
The release link base 171 is fixed, with a screw, to the bottom face in the bed portion 2b near the release slide base 151. One end of the release link base 171 is extended to a lower side of the slot 172b of the release link 172, and is provided with a projection 171a which is inserted into the slot 172b of the release link 172 in an upward direction. The other end of the release link base 171 is extended below the release driving arm 173, and is provided with a projection 171b in the upward direction.
The release driving arm 173 is a plate member having an L shape when seen on a plane. A bent portion at a central part of the release driving arm 173 is coupled to the projection 171b provided on the other end of the release link base 171, and is supported by the projection 171b so as to be rotatable in the horizontal direction. One end of the release driving arm 173 is formed with a slot 173a which vertically penetrates through the release driving arm 173 (in the Z-axis direction) and is extended in the X-axis direction. The projection 172a of the release link 172 is rotatably coupled into the slot 173a. The other end of the release driving arm 173 is provided with the projection 173b in the upward direction.
The release driving arm 173 converts the movement of the release link 172 in the Y-axis direction into a movement in the X-axis direction, and transmits this movement to the release slide base 151. More specifically, when the release link 172 is moved in the direction B along the Y-axis direction together with the operating plate 142, the release driving arm 173 is rotated around the projection 171b so that the projection 173b abuts on a lower end portion of the flange portion 151b of the release slide base 151. When the release link 172 is further moved in the direction B, the release slide base 151 is moved in the direction C′ against the biasing force of the coil spring 154 in the direction C.
Namely, the operating plate 142 and the release slide base 151 are coupled to each other through the release link base 171, the release link 172 and the release driving arm 173. The movement of the operating plate 142 in the Y-axis direction and the movement of the release slide base 151 in the X-axis direction are interlocked with each other through the interlocking mechanism 170 including the release link base 171, the release link 172 and the release driving arm 173. According to this configuration, the main shaft locking mechanism 160, the switching mechanism 150 and the air spray moving means 140 are interlocked with each other so that the thread discharging port 112 of the thread pipe 110 disposed at the front position becomes coincident with the thread hole 21b of the looper 21 disposed at the rear position, and the thread inserting port 111 of the thread pipe 110 disposed at the front position becomes coincident with the tip of the air nozzle 121 disposed at the spraying position P1 in the vertical and horizontal directions.
Next, description will be given to an operation of the sewing machine 1 having the above configuration.
Tilting Operation of Looper
During the stitching operation, the operating plate 142 is disposed on a side of a direction B′ as shown in
When threading the looper thread T through the thread hole 21b of the looper 21, first, the flywheel 7 is rotated manually by the operator to cause the indicator m1 to be coincident with the indicator m2 in the state in which the sewing machine 1 is stopped. Consequently, the rotating angle of the lower shaft 6 is positioned at a predetermined rotating angle, i.e., an angle at which the looper 21 interlocking with the lower shaft 6 through the looper driving shaft 22 is at the foremost moving position in the back and forth movement (see
Subsequently, when the lock button 144 is manually pushed by the operator, the small diameter portion 144a of the lock button 144 becomes movable along the permitting portion 142db of the slit 142d.
At this time, the operating plate 142 is moved in the direction B by the biasing force of the spring 143 so that the lock shaft 162 is moved in the direction B, whereby the tip portion thereof is inserted into the engaging portion 161a of the main shaft lock plate 161 (see
When the lock button 144 is pushed when the indicator m1 is not coincident with the indicator m2, the tip portion of the lock shaft 162 abuts on the end face of the main shaft lock plate 161 as shown in
Inside the bed portion 2b below the needles 4, the release link 172 coupled to the operating plate 142 is moved in the direction B so that the release driving arm 173 is rotated around the projection 171b and the projection 173b is caused to abut on the flange portion 151b of the release slide base 151. Because the biasing force of the spring 143 is stronger than the biasing force of the coil spring 154, the release slide base 151 is moved in the direction C′ against the biasing force of the coil spring 154 (see
When the release slide base 151 is moved in the direction C′, the tip portion of the release pin 152 is pulled out from the slot 24a of the looper driving arm 24, and is thus inserted only into the slot 23a of the looper support arm 23 (see
Due to this rotation, the looper 21 supported on the looper support arm 23 is disposed at the rear position so that the thread discharging port 112 of the thread pipe 110 becomes coincident with the thread hole 21b (see
Returning Operation of Looper
When returning the looper 21 tilted at the rear position, the operation lever 142c is first manually operated by the operator to move the operating plate 142 in the direction B′. Consequently, the lock shaft 162 is moved in the direction B′ so that the locked state of the lower shaft 6 is released. Therefore, the lower shaft 6 becomes rotatable (see
Subsequently, when the flywheel 7 is rotated manually by the operator, the looper driving shaft 22 is rotated interlockingly with the rotation of the lower shaft 6, and the looper driving arm 24 is swiveled interlockingly with the rotation of the looper driving shaft 22. When the looper driving arm 24 is swiveled to one end (the rearmost moving position in the back and forth movement of the looper 21), the slot 24a and the release pin 152 become coincident with each other so that the release slide base 151 is further moved in the direction C by the biasing force of the coil spring 154, whereby the release pin 152 is inserted into the slot 24a. Consequently, the looper driving arm 24 and the looper support arm 23 are coupled to each other through the release pin 152. Thus, the looper 21 and the lower shaft 6 are interlocked with each other, whereby it becomes possible to carry out the stitching operation.
As described above, according to the sewing machine 1 of the first exemplary embodiment, the main shaft locking mechanism 160, the switching mechanism 150 and the air spraying unit 120 are interlocked with each other by a single operation (i.e., without separate operations). When the lock button 144 is simply operated, the air nozzle 121 of the air spraying unit 120 can be moved to the spraying position P1 and the lower shaft 6 can be locked at the predetermined rotating angle. Furthermore, the looper 21 can be positioned at the rear position through the interlocking mechanism 170. Therefore, the operator of the sewing machine 1 does not need to use both hands in order to operate each of the mechanisms. In other words, it is possible to implement, by one hand, the alignment of the lower shaft 6, the lock/release of the lower shaft 6, the movement of the air nozzle 121, the tilt of the looper 21 and their returning operations. Consequently, the threading work is considerably simplified facilitated. Thus, the operability of the sewing machine 1 is significantly improved. In addition, the looper 21 is tilted to the rear position when matching the thread discharging port 112 of the thread pipe 110 and the thread hole 21b of the looper 21. Therefore, it is possible to carry out the threading work with a simple structure without requiring to pull away the thread passing through the looper 21 or to release the tension of the thread.
Next, a second exemplary embodiment of the invention will be described in detail with reference to
The second exemplary embodiment is different from the first exemplary embodiment in that a lever 244 (operation input means, a manual operating portion) and a main shaft locking mechanism 260 which is driven by the lever 244 are provided.
As shown in
As shown in
As shown in
The link member 263 has an L shape, and is supported rotatably by the support shaft 262 fixed to the frame 2 in a bent portion having an L shape. As shown in
The lock member 264 is a plate-shaped member which is rotated in a horizontal plane around the fulcrum shaft 262 and is fitted, in a radial direction, in the slit 261a of the main shaft lock plate 261 (a rotating member), and is set to have such a length as to be engageable with an inner part of the slit 261a of the main shaft lock plate 261 when it is rotated around the fulcrum shaft 262 and is thus disposed in parallel with the lower shaft 6. A spring hook 264a is provided on one of sides of the lock member 264. One end of a tension spring 265 (lock member biasing means) having the other end coupled to the spring hook 263a of the link member 263 is coupled to the spring hook 264a. In other words, the lock member 264 and the link member 263 form a two-layer structure in which they can be rotated coaxially and separately. The lock member 264 is constantly biased toward the spring hook 263a side positioned on one of the ends of the link member 263 by a biasing force of the tension spring 265 and is thus disposed on the spring hook 263a side.
The release link 172 coupled to the link member 263 is coupled to an operating plate 142 and can be moved in the Y-axis direction together with the operating plate 142 in the same manner as in the first exemplary embodiment. In the second exemplary embodiment, the operating plate 142 can also be operated by the lever 244 in the direction B and a direction B′. Therefore, it is not necessary to always provide the operating portions such as the lock button 144 and the operation lever 142c, and the spring 143 (the nozzle biasing means) of the first exemplary embodiment.
As shown in
When the lower shaft 6 is positioned at the predetermined rotating angle at which the indicators m1 and m2 are coincident with each other, both the link member 263 and the lock member 264 are disposed in parallel with the lower shaft 6 so that the lock member 264 is fitted in the slit 261a of the main shaft lock plate 261 to bring a state in which the rotation of the lower shaft 6 is locked as shown in
In the sewing machine according to the second exemplary embodiment, it is possible to interlock the main shaft locking mechanism 260, a switching mechanism 150 and an air spray moving mechanism 140 by a single operation (i.e., without operating them separately) in the same manner as in the first exemplary embodiment. Therefore, a threading work can be simplified considerably and carried out easily. In the same manner as in the first exemplary embodiment, moreover, the operator can carry out an operation by one hand.
Next, description will be given to a third exemplary embodiment of the invention. As shown in
The motor starting switch 361 can carry out ON/OFF switching by opening/closing a detecting portion 361a, and serves to output a signal for driving the motor 5 to a control portion (not shown) in an ON state in which the detecting portion 361a is pushed. The motor starting switch 361 is fixed to a frame 2 in a state in which the ON/OFF switching can be carried out by a movement of an operating plate 142 in a Y-axis direction as shown in
On the other hand, the motor stopping switch 362 can carry out the ON/OFF switching by opening/closing a detecting portion 362a and serves to output a signal for stopping the motor 5 to the control portion (not shown) in an ON state in which the detecting portion 362a is pushed. The motor stopping switch 362 is fixed to the frame 2 such that the ON operation is carried out in only a state in which the tip of the lock shaft 162 is engaged with an engaging portion 161a of the main shaft lock plate 161 by the movement of the operating plate 142 in the Y-axis direction (see
As shown in
The control portion 350 serves to decide that the main shaft locking mechanism 360 is set in an operable state when the lock shaft 162 is moved in a direction B in accordance with the input operation from the lock button 144 (the operation input means) and the motor starting switch 361 is thus turned ON, thereby inputting a start of the rotating and driving operation of the motor 5. Moreover, the control portion 350 carries out a control processing of deciding that the lower shaft 6 is positioned at the predetermined rotating angle by the ON operation of the motor stopping switch 362 through the movement of the lock shaft 162 in the direction B, thereby inputting the stop of the rotating and driving operation of the motor 5.
Description will be given to an operation of the main shaft locking mechanism 360 according to the third exemplary embodiment. When the lock button 144 is pushed so that the operating plate 142 is moved in the direction B by a biasing force of a spring 143, the tip of the lock shaft 162 abuts on the end face of the main shaft lock plate 161 and the operating plate 142 is stopped in the case in which the lower shaft 6 is not set at a predetermined rotating angle, that is, an angle at which the lock shaft 162 can be engaged with the engaging portion 161a of the main shaft lock plate 161 (an angle at which indicators m1 and m2 are coincident with each other) (see
Next, a fourth exemplary embodiment of the invention will be described in detail with reference to
The fourth exemplary embodiment is different from the first, second and third exemplary embodiments in that a looper support arm 423 supporting a looper 21 is tilted around a fulcrum shaft 422 which is different from a looper driving shaft 22 when the looper 21 is to be disposed at a rear position, i.e., a threading position by a looper tilting mechanism 450.
The looper support arm 423 according to the fourth exemplary embodiment has a lower end which is rotatably attached to an intermediate part of a looper driving arm 424 above the looper driving shaft 22 through the fulcrum shaft 422 provided in parallel with the looper driving shaft 22. In other words, in the looper tilting mechanism 450 according to the fourth exemplary embodiment, the looper support arm 423 for supporting the looper 21 is tilted in the middle in the case in which the looper driving shaft 22 to be a swiveling center of the looper 21 during a sewing work is set to be a center. A thread guide plate 413 is fixed to an upper part of the looper driving arm 424, and a thread pipe 110 is attached to the thread guide plate 413.
During the stitching work, the looper support arm 423 and the looper driving arm 424 are coupled to each other through a release pin 152 so that the looper 21 is rigidly supported on the looper driving arm 424 and is swiveled in accordance with a rotation of the looper driving shaft 22 (see
On the other hand, the release pin 152 is moved so that the looper support arm 423 can be rotated around the fulcrum shaft 422 with respect to the looper driving arm 424 and the looper 21 is tilted to a rearward side in a back and forth movement thereof. Then, the looper 21 is disposed in a threading position in which a thread hole 21b and a thread discharging port 112 are coincident with each other (see
In the sewing machine of the fourth exemplary embodiment, in the same manner as in the first exemplary embodiment, it is possible to interlock an air spraying unit 120, a main shaft locking mechanism 160 and the looper tilting mechanism 450 by an input operation from an interlocking mechanism 170. Consequently, it is possible to considerably simplify a threading work for inserting a looper thread T through the looper 21.
According to one or more exemplary embodiments of the invention, a coupling state of the looper and the looper shaft can be switched into a connection and a separation by the switching means. When the looper and the looper shaft are brought into the disconnected state by the switching means, the looper can be disposed in the rear position by the moving means. When the looper is disposed in the rear position, moreover, the thread hole of the looper can be coincident with the thread discharging port of the thread pipe disposed in the front position and the thread inserting port of the thread pipe disposed in the front position can be coincident with the tip of the nozzle disposed in the front position. In other words, by bringing the looper and the looper shaft into the disconnected state through the switching means and disposing the nozzle in the front position, it is possible to supply the air to the thread inserting port of the thread pipe and to insert the thread inserted from the thread inserting port by the air through the thread hole of the looper. Consequently, tweezers are not required for inserting the thread through the thread hole of the looper so that the threading work can be considerably simplified as compared with the case in which the thread is inserted through a manual work of an operator. Accordingly, it is possible to eliminate a complicatedness of a conventional threading work, thereby carrying out the threading work easily.
Moreover, the looper is disposed in the rear position to cause the thread hole of the looper to be coincident with the thread discharging port of the thread pipe. Therefore, it is possible to smoothly carry out the threading work without requiring to draw an upper thread laid over the looper and to release a tension of the upper thread.
According to one or more exemplary embodiments of the invention, it is possible to couple the looper support member to a thread pipe support member by sliding the coupling member when the looper support member and the thread pipe support member are disposed in the rear position. In other words, it is possible to switch the connection and disconnection of the looper and the looper shaft in the rear position to be a rotating range of the looper shaft and an oscillating range of the looper. Consequently, the looper separated from the looper shaft by the switching means can be connected within the oscillating range.
According to one or more exemplary embodiments of the invention, interlocking means is provided. Therefore, it is possible to position the main shaft at the predetermined rotating angle such that the thread pipe is placed in the front position interlockingly with an operation for disposing the nozzle in the spraying position and to bring the looper and the looper shaft into the disconnected state by the switching means. By the moving means, it is possible to dispose the loop in the rear position. In other words, it is possible to interlock the main shaft locking mechanism, the switching means and the air supplying means by one operation without operating them separately. Accordingly, the threading work can be considerably simplified and can easily be carried out. Moreover, there is provided the operation input means for manually operating the interlocking means. Consequently, it is possible to enhance an operability of the threading device by an operator.
According to one or more exemplary embodiments of the invention, when the operation input means is manipulated by the operator and the operation input means is switched from the holding position to the permitting position, the nozzle is moved from the standby position to the spraying position by the biasing force of the nozzle biasing means. Interlockingly therewith, moreover, the main shaft is positioned at the predetermined rotating angle by the main shaft locking mechanism and the looper and the looper shaft are brought into the disconnected state by the switching means.
In other words, by providing the nozzle biasing means, it is possible to move the nozzle to the spraying position and to position the main shaft at the predetermined rotating angle by simply manipulating the operation input means. By bringing the looper and the looper shaft into the disconnected state through the switching means, furthermore, it is possible to dispose the looper in the rear position by the moving means. Accordingly, the operator of the sewing machine does not need to use both hands when operating each of the mechanisms, and can thus implement the threading work for inserting the thread through the looper by either of the hands. Consequently, the operability of the sewing machine can be enhanced considerably so that the threading work can easily be carried out.
According to one or more exemplary embodiments of the invention, by the motor control means, the motor starts to be rotated and driven when the main shaft locking mechanism is brought into the operable state in accordance with the input operation from the operation input means. Therefore, also in the case in which the operation input means is operated when the main shaft is not disposed at the predetermined rotating angle, for example, the main shaft can be rotated to have the predetermined rotating angle at which the lock member can be fitted in an engaging portion of a rotating member. In the case in which the nozzle biasing means is provided, it is possible to position the main shaft at the predetermined rotating angle and to automatically stop the main shaft. When the detecting means detects that the main shaft is positioned at the predetermined rotating angle, moreover, the rotating and driving operation of the motor can be stopped automatically by the motor control means. In other words, it is possible to automatically stop the main shaft at the predetermined rotating angle by simply manipulating the operation input means irrespective of whether the main shaft is disposed at the predetermined rotating angle when the operator manipulates the operation input means and to dispose the looper in the rear position through the interlocking means, and furthermore, to dispose the nozzle in the spraying position. Then, it is possible to automatically stop the motor Consequently, it is possible to prevent a rotation of the motor which is not required for the threading work for inserting the thread through the looper. Thus, it is possible to execute the threading work very easily while preventing a waste of a power and an abrasion of the apparatus.
According to one or more exemplary embodiments the invention, the main shaft locking mechanism is stopped at the predetermined rotating angle by means of the rotating member fixed to the main shaft and the lock member to be engaged with the engaging portion of the rotating member. Moreover, the lock member can be energized in such a direction as to be engaged with the engaging portion by the lock member biasing means. Consequently, also in the case in which the main shaft is not disposed at the predetermined rotating angle, for example, it is possible to bring the lock member into an energizing state in such a direction as to be engaged with the engaging portion by manipulating the operation input means. By subsequently disposing the main shaft at the predetermined rotating angle, therefore, it is possible to position the main shaft at the predetermined rotating angle. In other words, the operation input means can be operated irrespective of whether the main shaft is disposed at the predetermined rotating angle, and furthermore, the lock member can be energized in such a direction as to be engaged with the engaging portion by the lock member biasing means. Therefore, the operator can implement each of the operations by either of the hands. Accordingly, the threading work for inserting the thread through the looper can be carried out very easily.
According to one or more exemplary embodiments of the invention, the lock member is fitted in the engaging portion of the rotating member in the axial direction. Consequently, it is possible to place the main shaft in a constant position.
According to one or more exemplary embodiments of the invention, the lock member is fitted in the engaging portion of the rotating member in the radial direction. Consequently, it is possible to place the main shaft in the constant position.
According to one or more exemplary embodiments of the invention, the link member and the lock member are provided to be coaxially and separately rotatable, and the link member and the lock member are coupled to each other through a tension spring. Therefore, when the input operation is carried out through the operation input means, for example, the link member is rotated and the lock member stands by in an abutting state on a peripheral edge of the rotating member in the radial direction even if the main shaft is not positioned at the predetermined rotating angle at which the lock member is fitted. Moreover, the lock member can be energized toward the center of the rotating member by the biasing force of the tension spring in this state. When the main shaft is then rotated and is disposed at the predetermined rotating angle, therefore, the lock member can be fitted in the engaging portion of the rotating member by a biasing force of the tension spring. In other words, the operation input means can be manipulated irrespective of whether the main shaft is disposed at the predetermined rotating angle. Therefore, it is possible to enhance the operability in the threading operation.
According to one or more exemplary embodiments of the invention, by the operation of the operating member, the thread pipe can be moved to the front position and the looper placed in the front position can be separated from the looper shaft, and the looper can be moved to the rear position. Thus, the threading work can be simplified so that a working efficiency can be enhanced.
According to one or more exemplary embodiments of the invention, by the operation of the operating member, it is possible to place the looper in the rear position and to move the nozzle to the spraying position. Therefore, the threading work can be simplified so that the working efficiency can be enhanced.
While description has been made in connection with exemplary embodiments of the present invention, it will be obvious to those skilled in the art that various changes and modification may be made therein without departing from the present invention. It is aimed, therefore, to cover in the appended claims all such changes and modifications falling within the true spirit and scope of the present invention.
Number | Date | Country | Kind |
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P.2006-308878 | Nov 2006 | JP | national |
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2865470 | Dec 1998 | JP |
Number | Date | Country | |
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20080134950 A1 | Jun 2008 | US |