The present invention relates to a loom similar to a gripping rapier loom and a weaving method using the loom, and particularly, to a special loom best suitable for weaving a precursor fiber fabric corresponding to the production of a carbon fiber and a fabric weaving method using the special loom.
A loom is used to produce a fabric obtained by mixing plural warp yarns and fill yarns. The loom is largely classified into a shuttle loom and a shuttle-less loom. In the weaving using the shuttle loom, plural warp yarns aligned in one direction through a mail of a heddle are guided so that a part of the warp yarns are moved up and a part of the warp yarns are moved down so as to form a rhombic opening between the warp yarns in a manner such that the heddle is moved up and down based on the weave texture. While the opening is formed, a shuttle for accommodating and holding a fill yarn bobbin is beaten into a shuttle path formed inside the opening. The fill yarn is drawn out from the bobbin accommodated inside the shuttle by the beating. When the beating ends, a dent which is disposed between the heddle and the cloth fell position swings toward the cloth fell position, so that the fill yarn is pressed into the cloth fell position. The weaving is performed by repeating these operations.
The weaving using the shuttle-less loom is different from the weaving using the shuttle loom in that the above-described shuttle is not used and the fill yarn directly passes through the opening formed by the warp yarns. The shuttle-less loom may be classified into plural types in accordance with a difference in the method of inserting the fill yarn into the opening. As one of representative looms, there is known a water jetting loom which loads a fill yarn on a water jetting stream so that the fill yarn is inserted into a shuttle opening. As the other looms, there is known a needle loom in which a fill yarn is gripped by a front end of a needle moving in a reciprocating manner inside an opening of warp yarns, the needle is moved in a reciprocating manner inside the same opening, and loops of the adjacent folded-back portions are sequentially connected and matched by a knitting needle so as to obtain a fabric or a rapier loom in which a rapier formed as a stab member is disposed at the left and right sides of the loom and a front end of a fill yarn is moved in a reciprocating manner to the inside or the outside of the opening by the entire weaving width or a half of the weaving width while the front end thereof is gripped or released by a carrier head of each front end of the left and right rapiers so that the fill yarn is directly inserted into the opening.
These conventional looms respectively have good and bad points. For example, in the shuttle loom, the fill yarn is reliably inserted, but the amount of the fill yarn accommodated and held by the shuttle is limited. Further, since the fill yarn is inserted while the shuttle flies along the shuttle path through the beating of the shuttle, the weight of the entire shuttle including the fill yarn is also limited. Accordingly, the mechanical beating sound generated by the fill yarn inserting operation is large, and hence a noticeable noise is generated. In one shuttle-less loom, noise may be solved by reducing the mechanical sound. However, for example, in the general shuttle-less loom, the operation of controlling the fill yarn length and the fill yarn end process at the ear portion of the edge of the weaving width is complex. Further, in the water jetting loom, various techniques of ensuring the straight traveling of the water are needed, and the adverse influence caused by the use of the water needs to be handled in various respects. Further, in the gripping rapier loom, mistakes may be caused during the operation of delivering the front end of the fill yarn by the carrier head or cutting the yarn end.
For example, when producing a carbon fiber under such circumstances, various precursor fibers are bound as one fiber bundle, and plural fiber bundles are disposed in parallel as a sheet. The fiber bundles are introduced into a flame-resistant furnace in the atmosphere of oxidization so as to be subjected to a flame-resistant process at 200 to 300° C. and are subsequently carbonized in a sintering furnace at 500 to 1500° C. in the atmosphere of nitrogen. The sintering speed at this time is generally 5 to 10 m/minute. Meanwhile, there is a recent demand for the improvement of the productivity, and hence the sintering speed and the total fiber fineness of the fiber bundle tend to increase. As the precursor fiber, acrylonitrile-based fibers are used in many cases.
As described above, when the flame-resistant process is continuously performed on various thick fiber bundles while running and being disposed in parallel in a sheet state, the maximal thickness of one fiber bundle increases, so that oxygen does not widely spread into the fiber bundles and the yarn is easily damaged due to the accumulation of heat. In order to prevent this problem, the flame-resistant process needs to be performed for a long period of time by decreasing the temperature of the flame-resistant process. However, since there is a difference in progress of the flame-resistant process between the inside and the surface of the fiber bundle, a nap may be raised or a yarn is damaged in the subsequent carbonizing process. For this reason, it is difficult to obtain the high-quality carbon fiber.
In order to continuously produce the carbon fiber, a method is proposed in which a carbonizable fiber filament bundle having thick fiber fineness is flattened as described above, the fiber filament bundle is disposed in parallel so as to become a band-like material, and the band-like material is sintered at a high temperature. However, in a case where a material obtained just by disposing the fiber bundle in a band shape is sintered at a high temperature, the nap of the single fiber forming the band-like material in the flame-resistant process or the ends of the damaged yarns is particularly wound on a roller inside a furnace or is tangled with the adjacent fiber bundles inside the furnace, and hence the more naps occur or the more yarns are damaged. As a result, the continuous sintering process needs to be stopped without any choice.
In order to solve these problems, for example, JP 10-266024 A (Patent Literature 1) proposes a method in which the precursor fiber bundle is guided inside the flame-resistant furnace in a zigzag shape by a rectangular guide groove to multi-stage guide rolls provided at the inlet and the outlet of the flame-resistant furnace and the precursor fiber bundle guided inside the flame-resistant furnace is maintained, through the guide groove, in a state where the cross-sectional shape thereof becomes a substantially rectangular shape in which the oblateness defined by the transverse width and the yarn thickness of the fiber bundle is 10 to 50.
Further, in order to exclude the above-described problems, for example, JP 51-75150 A (Patent Literature 2), JP 61-63718 A (Patent Literature 3), and U.S. Pat. No. 4,173,990 (Patent Literature 4) proposes a method in which various precursor fiber bundles formed in a sheet shape are formed by warp yarns and are mixed with fill yarns so as to form a fabric by weaving. Here, in Patent Literatures 2 and 3, one fill yarn is folded back toward the end of the entire weaving width so as to be mixed with the warp yarn. However, in Patent Literature 4, the rapier formed as a pair of double tubes is disposed at the left and right side of the loom in the width direction, the fill yarns are respectively inserted through the inner tubes of the left and right rapiers, the front ends of the respective fill yarns are gripped and conveyed by using the air pressure transferred to the outer tube of the rapier, and the respective fill yarns are folded back to the center portion inside the opening formed by the warp yarns. Here, the weaving is performed by alternately repeating the operations of inserting and separating the left and right rapiers into and from the opening with a predetermined time interval therebetween.
Meanwhile, in Patent Literatures 2 and 3, for example the flame-resistant process is performed on the precursor fiber bundles as the adjacent warp yarns to be introduced into the flame-resistant furnace for the process thereof while the fill yarns are inserted thereinto and the precursor fiber bundles are separated by the fill yarns so as to prevent the contacting or the lapping thereof. Then, in Patent Literatures 2 and 3, the fill yarn is automatically removed from the fabric after the flame-resistant process, and various fiber bundles subjected to the flame-resistant process are introduced into the carbonizing furnace while being simply aligned.
Patent Literature 1: JP 10-266024 A
Patent Literature 2: JP 51-75150 A
Patent Literature 3: JP 61-63718 A
Patent Literature 4: U.S. Pat. No. 4,173,990
Incidentally, the production speed of the conventional acrylonitrile-based fiber tow fabric is extremely slow so as to be 150 cm/minute as described in, for example, Patent Literature 3, and the recent production speed thereof becomes 400 cm/minute at maximum due to an increase in speed with the development of the technology. For this reason, a thick acrylonitrile-based tow of 30000 d or more as the precursor fiber bundle is used in the warp yarn in order to improve the productivity of the carbon fiber. Then, in order to obtain the high-quality carbon fiber which does not have any nap and damage yarns even in the subsequent carbonizing process by performing a uniform flame-resistant process on the thick acrylonitrile-based fiber bundle, the management thereof becomes more difficult. Thus, in the mechanical fill yarn inserting operation of the conventional art, it is difficult to realize a speed equal to or higher than the above-described speed.
Meanwhile, when the above-described precursor fiber fabric is obtained by the general weaving method in which the shuttle is beaten into the opening formed by the warp yarns so as to insert the fill yarn thereinto and the dent swings to the warp yarn so as to perform the beating for press-inserting the fill yarn to the cloth fell position, the warp yarn and the fill yarn scrape each other due to the beating, and hence there is a possibility that a damage may occur in the precursor fiber bundle which needs to be subjected to the delicate process even in the subsequent carbonizing process. For this reason, in this kind of fabric, the beating is not performed. Then, the fill yarn is inserted into the warp yarn in a zigzag shape at a predetermined pitch as illustrated in Patent Literatures 3 and 4 by adjusting the warp yarn transfer speed.
At this time, for example, when the precursor fiber fabric is produced by the general gripping rapier loom in a manner such that the beating is not performed inside the opening formed by the warp yarns with thick fiber fineness as plural long fiber bundles and the front end of the fill yarn is delivered at the center in the weaving width from one gripper provided at the front end of the pair of rapiers inserted into the opening from the left and right sides of the loom to the other gripper and these operations are repeated, there is a need to reliably perform the delivery of the front end of the fill yarn while paying more attention compared to the conventional method. Further, when the respective front ends of two left and right fill yarns are gripped and conveyed by the front end of the tube as in the tubular rapier loom disclosed in Patent Literature 4, more mistakes may occur compared to the gripper having a mechanical structure in the general gripping rapier loom, and hence it becomes more difficult to deliver the fill yarn between the pair of tubular rapiers.
The invention is made to solve the above-described problems, and it is an object of the invention to provide a loom capable of realizing an increase in warp yarn conveying speed compared to the conventional art, reliably separating respective warp yarns, for example, when weaving a precursor fiber fabric for a carbon fiber formed by a fiber bundle having a thick fiber fineness as a warp yarn, and realizing an increase in fill yarn inserting speed without raising a nap in a precursor fiber forming a fiber bundle and to provide a weaving method using the loom.
Such an object is effectively attained by the first basic configuration of the invention as a loom including: first and second fill yarn holding and conveying rods which are disposed at the left and right sides of an opening formed by plural warp yarns aligned while running at a predetermined speed in one direction and are repeatedly inserted into and separated from the opening toward the center of the weaving width in a synchronized state; a single fill yarn conveyor which is selectively gripped by opposite ends of the first or second fill yarn holding and conveying rod and is alternately held and conveyed by the first or second fill yarn holding and conveying rod; first and second rod operating units which cause the first and second fill yarn holding and conveying rods to be inserted into the opening in a synchronized state and to be withdrawn from the opening to the outside; and first and second fill yarn conveyor gripping and releasing units which are fixed to the opposite ends of the first and second fill yarn holding and conveying rods and alternately repeat operations of gripping, releasing, and delivering the fill yarn conveyor.
Further, the above-described object is attained by a weaving method having the following basic configuration and using the loom, and hence a high-quality fabric may be obtained with high productivity.
That is, there is provided a method of weaving a fabric including: inserting the first fill yarn holding and conveying rod into the opening toward the center in the weaving width inside the opening when the fill yarn conveyor is gripped by the gripping and releasing unit of the first fill yarn holding and conveying rod; inserting the second fill yarn holding and conveying rod into the opening toward the center in the weaving width inside the opening along with the inserting of the first fill yarn holding and conveying rod; delivering the fill yarn conveyor gripped by the first fill yarn holding and conveying rod at the center in the weaving width inside the opening to the gripping and releasing unit of the second fill yarn holding and conveying rod; and separating the first and second fill yarn holding and conveying rods to the outside of the opening after the delivery ends.
According to the preferred embodiment of the loom, each of the first and second rod operating units may include a linear motor and the first and second fill yarn holding and conveying rods may be operated by the linear motors. Further, the first and second gripping and releasing units may include first or second electromagnetic grip or first or second air chuck. The operations of gripping and releasing the fill yarn conveyor by the first or second electromagnetic grip or the first or second air chuck may be alternately performed at the center in the weaving width. Further, the fill yarn conveyor may include a bobbin holding frame which grips a fill yarn bobbin so that a fill yarn is unwound therefrom and first and second subject gripping and releasing portions which are provided in the bobbin holding frame so that the first and second fill yarn holding and conveying rods are alternately gripped and released by the first and second gripping and releasing units.
Further, preferably, the bobbin holding frame includes a drawing port through which the fill yarn unwound from the fill yarn bobbin is drawn to the outside of the frame and integrally includes a cylindrical member that horizontally protrudes to the outside of the frame by sharing the drawing port at the same plane as that of the bobbin holding frame. Then, the first and second fill yarn holding and conveying rods may include a confirmation unit which confirms whether the operation of delivering the fill yarn conveyor is reliably performed. The confirmation unit may include a piezoelectric member that confirms the operation of gripping the fill yarn conveyor by the first or second electromagnetic grip or the first or second air chuck, and a central control unit may receive an electric signal from the piezoelectric member and causes coil current of the second or first electromagnetic grip or air pressure of the first or second air chuck to be disappeared. In the representative embodiment of the warp yarn and the fill yarn, the warp yarn may be formed as a precursor fiber bundle of a carbon fiber, the fill yarn may be formed as a carbon fiber bundle, and the average conveying speed of the fill yarn conveyor may be 10 to 40 m/minute. From the viewpoint of improving the productivity, 15 m/minute is more desirable. Then, from the viewpoint of delivering the fill yarn conveyor, 30 m/minute is more desirable.
According to the most characteristic configuration of the device of the invention, for example, when the linear motor is used in the rod operating unit as described above, the fill yarn may be inserted at the speed four times the case of the servo motor capable of increasing the speed twenty times the speed of the mechanical driving such as gear driving or hydraulic driving. Further, the fill yarn may be inserted without substantially generating the impact sound in addition to the silent driving sound of the linear motor since the operation of delivering the fill yarn conveyor is performed in a manner such that the fill yarn conveyor is delivered by using the magnetic force generated by alternately repeating the excitation and the demagnetization of the electromagnetic coils respectively provided in the gripping and releasing units of the front end of the rod. As a result, any problem caused by noise does not occur. As described above, since the precursor fabric is woven by using the warp yarn as the precursor fiber bundle and the fill yarn as the carbon fiber bundle, the tangling or the lapping between the warp yarns is prevented. Further, the flame-resistant step and the carbonizing step to be performed later may be reliably and continuously performed at a high speed in accordance with an increase in the fill yarn inserting speed. Furthermore, it is possible to obtain the high-quality carbon fiber which is not non-uniformly processed and has a small amount of raised naps without the influence of the fast speed.
Furthermore, the specific operation corresponding to the above-described embodiment will be proved by the description of the embodiment below.
Hereinafter, a representative embodiment of the invention will be described in detail by referring to the drawings.
In
A heddle stand 8 is disposed between the second dent stand 3b and a cloth fell roll 7. The plural upper and lower warp yarns Wa which are separately arranged according to the weave texture through the second dent stand 3b subsequently pass through mails of a predetermined number of heddles (not illustrated) arranged in the same way according to the weave texture in the heddle stand 8. When the heddle 8a moves up and down based on the weave texture, plural warp yarns Wa intersect one another in the weaving width direction so as to form an opening (not illustrated) into which the fill yarn is inserted. In order to insert the fill yarn into the opening, a fill yarn inserting device (not illustrated) as the most characteristic constituent of the invention is disposed at left and right portions near the heddle stand 8 at the cloth fell side of the heddle stand 8.
According to the embodiment, since the beating by the dent is not performed, the reed for the beating is not provided. For this reason, in the embodiment, the cloth fell roll 7 is not intermittently driven, but is continuously driven so as to match the warp yarn supply speed. However, in a case where the beating is performed as in the normal case, the reed for the beating is provided, and the cloth fell roll 7 may be also driven intermittently so as to match the beating timing.
Next, a loom and a weaving method for a fiber fabric of a precursor of a carbon fiber as a representative embodiment of the fill yarn inserting device constituting a characteristic constituent of the invention in the loom with the above-described configuration will be described in detail by referring to the drawings. Furthermore, in the description below, the configurations of the respective constituents of the loom and the dimensions of the respective constituents will be specifically described, but these dimensions and the like are also the dimensions of the embodiments. Of course, the dimensions are not limited by these values.
The fill yarn inserting device 10 of the embodiment is disposed near the downstream side of the heddle stand 8 in the warp yarn running direction. A base 11 which has a length substantially three times the weaving width is provided in the weaving width direction (the left and right direction of
As illustrated in
Further, in the embodiment, first and second linear motors 24a and 24b which are used in a part of a preferred embodiment of the invention are used in the operating units 19 and 20 of the first and second fill yarn holding and conveying rods 14 and 15. Other than the linear motor, for example, a hydraulic cylinder, various gears, or a servo motor may be employed. However, for example, in a mechanical driving of the gear or the like, the driving speed is 0.2 m/second at best. Then, even in the servo motor capable of realizing the fast driving, the driving speed of 1 m/second may be realized at maximum. On the contrary, in the driving of the linear motor, the maximal driving speed may be set to 4 m/second. Further, a highly precise positioning control may be performed in the driving. Meanwhile, the present carbon fiber sintering speed is just 5 to 10 m/minute as described above, but in order to improve the productivity, the faster sintering speed is demanded. In this way, when the precursor fiber fabric weaving speed may be set to 4 m/second, the sintering speed may be also increased to 20 m/minute, and hence the step of producing the precursor fiber fabric, the flame-resistant step, and the carbonizing step may be continuously performed. Here, in a case where the above-described fast speed is not needed, a configuration may be employed in which the servo motor capable of performing a highly precise electronic control is used and the first or second fill yarn holding and conveying rod 14 or 15 is operated.
As schematically illustrated in
As illustrated in
The fill yarn conveyor 16 is formed as a bobbin holding frame 22 which supports a bobbin (fill yarn bobbin) 21 so as to be rotatable about its axis. As illustrated in
Further, a fill yarn drawing hole is formed at the center of the closing frame 22a-3. Further, a fill yarn drawing tube 25 is formed at the center of the closing frame 22a-3 so as to extend outward in parallel to the first and second opening frames 22a-1 and 22a-2. The inner space of the fill yarn drawing tube 25 communicates with the fill yarn drawing hole, and the fill yarn We which is unwound from the fill yarn bobbin 21 held by the bobbin holding frame 22 is delivered to the outside while passing through the inside of the fill yarn drawing hole and the fill yarn drawing tube 25. As illustrated in the enlarged view of in
As illustrated in
Furthermore, in the example illustrated in the drawing, the electromagnetic grip is employed as the first and second gripping and releasing units 17 and 18 which grip and release the fill yarn conveyor 16, but an air chuck may be used instead of the electromagnetic grip. In this case, the introduction and the discharge of the air pressure are alternately performed by the air supply and discharge signal sent from the control panel 12.
In addition, in the embodiment, as illustrated in
In the embodiment, since the protruding length of the fill yarn drawing tube 25 from the bobbin support center is set to be long, the fill yarn We which is unwound from the bobbin 21 may move close to the cloth fell roll 7 (
The opening ends of the first and second opening frame 22a-1 and 22a-2 are provided with the first and second subject gripping and releasing portions 30 and 31 which protrude outward in parallel to the closing frame 22a-3. In the first and second subject gripping and releasing portions 30 and 31, the fill yarn conveyor 16 is delivered by alternately and repeatedly gripping and releasing the fill yarn conveyor 16 using the first and second gripping and releasing units 17 and 18 fixed to the front ends of the first and second fill yarn holding and conveying rods 14 and 15 at the center of the weaving width inside the warp yarn opening.
Further, in the embodiment, passage confirming units 17d and 18d that confirm the operation of reliably passing the fill yarn conveyor 16 are integrally attached to the side surfaces of the first and second gripping and releasing units 17 and 18 fixed to the front ends of the first and second fill yarn holding and conveying rods 14 and 15. When the control panel 12 receives electric or magnetic passage signals from the passage confirming units 17d and 18d, the input and the interruption of the current to the electromagnetic coil 17c which is accommodated and fixed to the second rooms 17b and 18b of the first and second gripping and releasing units 17 and 18 are automatically performed. For example, in a state where the first gripping and releasing unit 17 grips the fill yarn conveyor 16 and the second gripping and releasing unit 18 does not grip the fill yarn conveyor 16 in an empty state, the first and second linear motors 24a and 24b are driven in a synchronized state so that the first and second fill yarn holding and conveying rods 14 and 15 are inserted and moved in a direction in which the inside of the opening of the warp yarn Wa approaches the center in the weaving width from the left and right ends of the base 11. At this time, current is supplied to the electromagnetic coil 17c of the first gripping and releasing unit 17, and current is not supplied to the electromagnetic coil (not illustrated) of the second gripping and releasing unit 18. Then, the first subject gripping and subject releasing unit 30 is suctioned to the first room 17a of the first gripping and releasing unit 17 by the magnetic force generated by the electromagnetic coil 17c of the first gripping and releasing unit 17.
As the confirmation unit 17d of the first gripping and releasing unit 17, the confirmation unit 18d is provided at the outer surface of the second gripping and releasing unit 18 so as to confirm the existence of the first gripping and releasing unit 17 when the first and second fill yarn holding and conveying rods 14 and 15 move in a direction in which both rods approach each other so that the first gripping and releasing unit 17 of the fill yarn conveyor 16 at the center in the weaving width inside the opening approaches the second gripping and releasing unit 18 fixed to the front end of the second fill yarn holding and conveying rod 15 or the guide pins 30c and 31c provided in the first gripping and releasing unit 17 are fitted to the pair of pin guide grooves 18h (not illustrated) formed in the second gripping and releasing unit 18. As the confirmation units 17d and 18d, a piezoelectric element or a proximity switch may be exemplified. Electric signals from the confirmation units 17d and 18d are sent to a driving source (not illustrated) of the electromagnetic coil 17c through a central control unit inside the control panel 12 so as to interrupt the coil current of the electromagnetic coil 17c and input the driving power to the counter electromagnetic coil (not illustrated) so that current flows to the electromagnetic coil.
Next, the weaving method using the loom according to the embodiment with the above-described configuration will be described in detail by referring to the drawings.
In
Here, in the embodiment, the acrylonitrile-based fiber subjected to the general process after the fiber spinning is used in the warp yarn Wa, and the number of filaments of one precursor fiber bundle is 50 K (50000), and the carbon fiber bundle of which the number of filaments is 1 K (1000) is used in the fill yarn We. The reason why the carbon fiber is used in the fill yarn We is because various problems occurring when performing a flame-resistant process on the precursor fabric subjected to the weaving may be prevented. Specifically, if the fiber bundle which is formed of the same material as that of the warp yarn Wa is used as the fill yarn We, when performing the flame-resistant process on the precursor fiber, the fiber thickness increases at the intersection portion between the fill yarn We and the warp yarn Wa as the precursor fiber bundle, the heat storage amount of the intersection portion becomes larger than the heat storage amounts of the other portions, and the heat transfer speed at the intersection portion becomes slow. For this reason, the uniform flame-resistant process may not be easily performed between the surface side constituting fiber and the inner side constituting fiber of the intersection portion. As a result, this non-uniform flame-resistant process also affects the subsequent carbonizing process, and hence the non-uniform process is performed on the carbon fiber as the finished product in many cases. Thus, the high-quality product may not be easily obtained. In order to perform the uniform process by preventing the non-uniform flame-resistant process, the carbon fiber bundle which is carbonized in advance is used in the fill yarn We in the embodiment.
The plural upper and lower warp yarns Wa which are separately arranged according to the weave texture through the second dent stand 3b subsequently pass through the mails of a predetermined number of heddles (not illustrated) arranged according to the weave texture in the heddle stand 8. When four heddles 8a move up and down according to the weave texture, the plural warp yarns Wa intersect one another in the weaving width direction so as to form an opening into which the fill yarn (not illustrated) is inserted. In order to insert the fill yarn into the opening, a fill yarn inserting device (not illustrated) as the most characteristic constituent of the invention is disposed at the left and right portions near the heddle stand 8 on the cloth fell side of the heddle stand 8.
According to the embodiment, since the beating by the dent is not performed, the reed for the beating is not provided. For this reason, in the embodiment, the cloth fell roll 7 is not intermittently driven, but is continuously driven so as to match the warp yarn supply speed. However, in a case where the beating is performed as in the normal case, the reed for the beating is provided, and the cloth fell roll 7 may be also driven intermittently so as to match the beating timing.
While the openings are alternately formed, the linear motor 24 and the electromagnetic coil 17c are driven while being controlled by various signals sent from the central control unit provided in the control panel 12. In
Now, the warp yarns Wa start to run, and four heddles 8a alternately move up and down according to the weave texture. In the embodiment, various warp yarns Wa are separated into two upper and lower groups as described above, the warp yarns Wa of one group sent from the upper side pass through one mail of one plated heddle 8a, and the warp yarn Wa of one group sent from the lower side passes through the other mail. Then, in this state, the respective heddles 8a are alternately moved up and down at every other position.
When the initial opening is formed, the first and second linear motors 24a and 24b are driven in a direction in which both motors approach each other, so that the first and second fill yarn holding and conveying rods 14 and 15 are inserted into the opening. At this time, the fill yarn We is unwound from the bobbin 21 with the movement of the fill yarn conveyor 16 gripped by the first gripping and releasing unit 17 of the second fill yarn holding and conveying rod 14, and is drawn from the front end of the fill yarn drawing tube 25 of the bobbin holding frame 22 so that the fill yarn We is extracted toward the center in the weaving width inside the opening. Here, when the first and second gripping and releasing units 17 and 18 of the first and second fill yarn holding and conveying rods 14 and 15 approach the center in the weaving width, for example, the pair of guide pins 31c and 31c protruding from the second subject gripping and subject releasing unit 31 of the bobbin holding frame 22 approach the pair of pin guide grooves 18h and 18h of the second gripping and releasing unit 18 of the second fill yarn holding and conveying rod 15, the approaching with respect to the pin guide grooves 18h and 18h is detected by a proximity switch. Then, when the guide pins 31c and 31c are fitted to the pin guide grooves 18h and 18h, the contact pressure is detected by a piezoelectric element. Accordingly, an electric signal is transmitted to the central control unit, so that the current of the electromagnetic coil 17c is interrupted and the current flows to the electromagnetic coil (not illustrated) of the second gripping and releasing unit 18. As a result, the gripping of the fill yarn conveyor 16 by the first gripping and releasing unit 17 is released, and the fill yarn conveyor 16 is gripped and fixed by the second gripping and releasing unit 18. Then, the delivery of the fill yarn conveyor 16 ends.
When the delivery ends, the driving of the first and second linear motors 24a and 24b is reversely performed, so that the first and second fill yarn holding and conveying rods 14 and 15 pass through the same opening so as to return to the original standby position outside the opening. During the returning operation, the fill yarn We is continuously unwound from the bobbin 21 delivered from the first fill yarn holding and conveying rod 14 to the second fill yarn holding and conveying rod 15, and is drawn out from the front end of the fill yarn drawing tube 25 of the bobbin holding frame 22. Then, the fill yarn We is directed toward the weaving width end outside the opening, so that the remaining half of the fill yarn outside the opening is inserted. When the first and second fill yarn holding and conveying rods 14 and 15 are returned to the standby position while the second fill yarn holding and conveying rod 15 grips the fill yarn conveyor 16, the heddle 8a at one position moves downward and the heddle 8a at the other position moves upward, so that a new opening is formed by the inversing of the intersection of the warp yarns Wa. When the opening is formed, the driving of the first and second linear motors 24a and 24b in the fill yarn inserting direction starts, so that the first and second fill yarn holding and conveying rods 14 and 15 are inserted to the center in the weaving width direction inside the opening.
At this time, the fill yarn conveyor 16 is continuously gripped by the second fill yarn gripping and releasing unit 18 fixed to the second fill yarn holding and conveying rod 15. For this reason, the fill yarn We of the right half of
Regarding the inserting speed of the fill yarn We of the invention, since the first and second linear motors 24a and 24b are used, the maximal running speed of the linear motor rotor 27 (movable base 29) is 4 m/second, and the maximal running speed may be four times the maximal speed of the servo motor capable of realizing a high speed compared to, for example, the mechanical driving such as gear driving or hydraulic driving. Further, since any impact sound is not substantially generated when delivering the fill yarn conveyor 16 in addition to the silent driving sound of the linear motor, any problem caused by noise does not occur. In this way, the flame-resistant step and the carbonizing step may be reliably performed at a high speed in accordance with an increase in the fill yarn inserting speed. Further, the high-quality carbon fiber may be obtained without the influence caused by an increase in the fill yarn inserting speed.
1 creel stand
2 cone (warp yarn bobbin)
3
a first dent stand
3
b second dent stand
4 final guide
5
a upper guide roll group
5
b lower guide roll group
6 guide
7 cloth fell roll
8 heddle stand
8
a heddle
10 fill yarn inserting device
11 base
11
a,
11
b sheet width regulating roll
12 control panel
14, 15 first and second fill yarn holding and conveying rods
16 fill yarn conveyor
17, 18 first and second gripping and releasing units
17
a (18a) first yarn
17
b (18b) second yarn
17
c electromagnetic coil
17
d,
18
d confirmation unit (piezoelectric element, proximity switch)
17
h,
18
h pin guide groove
19, 20 first and second rod operating units
21 bobbin (fill yarn bobbin)
22 bobbin holding frame
22
a-1, 22a-2 first and second opening frames
22
a-3 closing frame
24 linear motor
24
a,
24
b first and second linear motors
25 fill yarn drawing tube
26 linear motor stator
26
a stator body
26
b electromagnetic coil
27 linear motor rotor
28 linear guide
29 movable base
29
a linear scale
30, 31 first and second subject gripping portion and subject releasing portion
30
a,
31
a iron block
30
b,
31
b synthetic resinous cover
30
c,
31
c guide pin
Wa warp yarn
We fill yarn
Number | Date | Country | Kind |
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2011-118685 | May 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/063080 | 5/22/2012 | WO | 00 | 11/27/2013 |