CN109440254B - 360-degree rotary brocade big fiber structure - Google Patents
360-degree rotary brocade big fiber structure Download PDFInfo
- Publication number
- CN109440254B CN109440254B CN201811611627.5A CN201811611627A CN109440254B CN 109440254 B CN109440254 B CN 109440254B CN 201811611627 A CN201811611627 A CN 201811611627A CN 109440254 B CN109440254 B CN 109440254B
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- Prior art keywords
- lifting
- lifting rope
- fixed
- brocade
- rope
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- 239000000835 fiber Substances 0.000 title abstract description 24
- 238000009941 weaving Methods 0.000 claims abstract description 26
- 230000005484 gravity Effects 0.000 claims description 3
- 238000000034 method Methods 0.000 description 10
- 239000000463 material Substances 0.000 description 4
- 230000002035 prolonged effect Effects 0.000 description 3
- 238000009434 installation Methods 0.000 description 2
- 238000004519 manufacturing process Methods 0.000 description 2
- 230000003068 static effect Effects 0.000 description 2
- RYGMFSIKBFXOCR-UHFFFAOYSA-N Copper Chemical compound [Cu] RYGMFSIKBFXOCR-UHFFFAOYSA-N 0.000 description 1
- BQCADISMDOOEFD-UHFFFAOYSA-N Silver Chemical compound [Ag] BQCADISMDOOEFD-UHFFFAOYSA-N 0.000 description 1
- 238000005299 abrasion Methods 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 229910052802 copper Inorganic materials 0.000 description 1
- 239000010949 copper Substances 0.000 description 1
- 230000007547 defect Effects 0.000 description 1
- 239000006185 dispersion Substances 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- PCHJSUWPFVWCPO-UHFFFAOYSA-N gold Chemical compound [Au] PCHJSUWPFVWCPO-UHFFFAOYSA-N 0.000 description 1
- 229910052737 gold Inorganic materials 0.000 description 1
- 239000010931 gold Substances 0.000 description 1
- 230000000149 penetrating effect Effects 0.000 description 1
- 229910052709 silver Inorganic materials 0.000 description 1
- 239000004332 silver Substances 0.000 description 1
Classifications
-
- D—TEXTILES; PAPER
- D03—WEAVING
- D03C—SHEDDING MECHANISMS; PATTERN CARDS OR CHAINS; PUNCHING OF CARDS; DESIGNING PATTERNS
- D03C3/00—Jacquards
- D03C3/24—Features common to jacquards of different types
- D03C3/42—Arrangements of lifting-cords
-
- D—TEXTILES; PAPER
- D03—WEAVING
- D03C—SHEDDING MECHANISMS; PATTERN CARDS OR CHAINS; PUNCHING OF CARDS; DESIGNING PATTERNS
- D03C3/00—Jacquards
- D03C3/24—Features common to jacquards of different types
- D03C3/44—Lingoes
Abstract
The invention discloses a 360-degree rotary brocade large fiber structure, wherein a plurality of groups of lifting heads are distributed at the bottom of a lifting machine in parallel, the lifting heads are movably connected with the lifting machine up and down, the bottoms of the lifting heads are respectively fixed with one end of a lifting rope A, the other end of the lifting rope A is connected with a rotating shaft of a movable pulley, the number and the positions of the lifting ropes B respectively correspond to the movable pulley, one end of the lifting rope B is fixed with a transverse plate, the other end of the lifting rope B bypasses the movable pulley and downwards passes through a through hole formed in the transverse plate, a threading ring is fixed, one end of the lifting rope C passes through the threading ring and then is connected with the other end of the lifting rope C to form a threading opening for threading a warp, and a heavy hammer rod is fixed at the bottom of the lifting rope D. According to the 360-degree rotary brocade large fiber structure, through the action of the movable pulleys, the lifting height and the lifting speed of the brocade warp can be effectively improved, and the weaving efficiency of the brocade can be conveniently improved.
Description
Technical Field
The invention relates to the technical field of brocade weaving machines for lifting large fibers, in particular to a 360-degree rotary brocade large fiber structure.
Background
Brocade is a representative of the human non-material cultural heritage of the united nations. Different from other weaving methods, the brocade material is elegant and attractive, and expensive materials such as gold wires, silver wires, copper wires and the like are favored. Therefore, the brocade is the most exquisite and luxury in the applications of dragon gown, crown dress, and official and religious, noble costumes of doctor-far class, or civilian wedding celebration costumes for the royal. With the development of weaving technology, the brocade can copy a long roll to be a wonderful unique year through picking and weaving.
The applicant previously submitted a patent of brocade macrofiber structure for rapid weaving, and found that in practical use, the lifting stroke of the lifting machine is limited, which results in troublesome threading of weft between lifted warp and non-lifted warp, even possibly causing misoperation. If the stroke of the lifting machine is directly increased, although the lifting stroke of the warp can be improved, the cost of the lifting machine is increased too high, and in addition, the time for lifting the warp can be increased due to the increase of the stroke of the lifting machine, so that the brocade weaving efficiency is reduced.
In addition, in the actual production process, the large fibers are worn and broken after being woven for a period of time; at this time, the machine is stopped and the large fiber is replaced; because the number of warp threads in the brocade weaving process is large, one warp thread corresponds to one large fiber, the service conditions of different large fibers are different, the service lives of the warp threads are slightly different, if the warp threads are stopped for replacement every time one large fiber breaks, the large fibers are frequently replaced due to the large number of the large fibers, and the weaving of a loom is seriously affected; it is common that when one of the large fibers breaks, although the other large fibers do not break, there is certainly a different degree of abrasion, and there are many to break, so that it takes a lot of time to replace virtually all the large fibers of the loom. And even so, it is normal to replace a batch of large fibers every month. The influence on brocade weaving is still relatively large.
Disclosure of Invention
The invention aims at: the defects of the prior art are overcome, and the 360-degree rotary brocade large fiber structure is provided, so that the lifting height and the lifting speed of the brocade warp can be effectively improved through the action of the movable pulley, and the weaving efficiency of the brocade is conveniently improved; through the action of the movable pulleys, the lifting rope C can automatically rotate in each lifting process, so that the lifting stress point of the lifting rope C is changed each time, the stress points of the lifting rope C are uniformly dispersed, the service life of the lifting rope C is prolonged, and the weaving efficiency of brocade is indirectly improved; through the action of the lifting heavy bar, the lifting rope A is always straightened, so that lifting acting force of a lifting machine borne by the lifting head can be effectively applied to the movable pulley, and the synchronism of the stress of the movable pulley and the stress of the lifting head and the synchronism of actions are maintained; the length of the lifting heavy bar is longer than the lifting stroke of the corresponding lifting head, so that the phenomenon that the action synchronism of the movable pulley and the lifting rope A is influenced due to interference between the bottom end of the lifted lifting heavy bar and the top of the adjacent lifting heavy bar which is not lifted due to shaking in the descending process is avoided; the slots corresponding to the lifting ropes B in the same group are positioned in the corresponding operation slots of the group, so that the lifting ropes B are convenient to install, and the installation efficiency of the lifting ropes B is improved; the loop wire formed by the lifting rope C can not be wound in the lifting process due to the action of the horizontal cross rod, so that the normal weaving of the loom is ensured.
The technical scheme adopted by the invention is as follows:
the utility model provides a 360 big fine structure of degree rotation brocade, includes the lift machine that is fixed in brocade loom top, the bottom parallel distribution of lift machine has the multiunit to carry the pull head, and the pull head of every group carries the pull head and is two rows of quantity and position corresponding, and the quantity and the position of every row of pull head are corresponding respectively, carry the pull head through drive arrangement respectively with lift machine upper and lower swing joint, the bottom of carrying the pull head is fixed with the one end of carrying rope A respectively, the other end of carrying rope A is connected with the pivot of movable pulley, the below of movable pulley is equipped with the diaphragm fixed with the brocade loom, the top of diaphragm is fixed with many carrying ropes B, the quantity and the position of carrying rope B correspond respectively with movable pulley, carry the one end and the diaphragm of rope B are fixed, behind the movable pulley, downwards pass the through-hole that the diaphragm established and be fixed with the wire loop, carry rope C's one end and the other end meet with the other end after passing the wire loop, carry the bottom that rope C formed is used for carrying rope D through the fixed bottom that the rope D that is used for carrying rope D that the warp was worn.
According to the further improved scheme, an insert is fixed at one end of the lifting rope B, and one end of the lifting rope B is matched and fixed with a slot arranged on the top surface of the transverse plate through the insert.
According to a further improvement scheme, lifting ropes B corresponding to two rows of lifting heads in the same group and fixing ends of the transverse plates are respectively located between the two rows of lifting ropes A in the group.
According to a further improved scheme, each group of lifting heads on the transverse plate is provided with a strip-shaped operation notch, and the slots corresponding to the lifting ropes B in the same group are all positioned in the corresponding operation notches.
According to the invention, the distance between the through holes corresponding to the two adjacent rows of lifting ropes B is equal, and the distance between the through holes corresponding to the two adjacent lifting ropes B in the same row is equal.
According to a further improvement scheme, a lifting heavy bar is arranged in the middle of the lifting rope A, and the gravity center of the lifting heavy bar and the lifting rope A connected with the lifting heavy bar are on the same straight line.
According to the invention, the heights of all the lifting heavy bars are the same, the lengths of all the lifting heavy bars are the same, and the lengths of the lifting heavy bars are larger than the lifting strokes of the corresponding lifting heads.
According to a further improved scheme, a threading ring is fixed at the top end of the lifting rope D, one end of the lifting rope C sequentially penetrates through the threading ring arranged at the bottom of the lifting rope B and the threading ring arranged at the lifting rope D and then is connected with the other end to form a loop, and warp threads penetrate through the threading ring arranged at the top end of the lifting rope D.
Or in a further improvement scheme of the invention, one end of the lifting rope D is fixed at the top of the heavy hammer rod, the other end of the lifting rope D passes through a loop formed by the lifting rope C and then is fixed with the top of the heavy hammer rod to form a semi-loop, and warp threads respectively pass through the bottom of the loop formed by the lifting rope C and the top of the semi-loop formed by the lifting rope D.
According to a further improvement scheme, the horizontal cross bars are respectively penetrated through the loop wires formed by each row of lifting ropes C, and two ends of each horizontal cross bar are fixed on the brocade weaving machine.
In a further development of the invention, the horizontal cross bar is located at the upper part of the loop formed by the lifting rope C.
The invention further adopts the improvement that the intervals between two adjacent rows of lifting ropes C are respectively equal.
The invention has the beneficial effects that:
according to the 360-degree rotary brocade large fiber, the lifting height and the lifting speed of a brocade warp can be effectively improved through the action of the movable pulley, and the weaving efficiency of the brocade can be conveniently improved.
Secondly, according to the 360-degree rotary brocade big fiber, through the action of the movable pulley, the lifting rope C can automatically rotate in each lifting process, so that the lifting stress point of the lifting rope C is changed each time, the stress points of the lifting rope C are uniformly dispersed, the service life of the lifting rope C is prolonged, and the weaving efficiency of the brocade is indirectly improved.
Thirdly, according to the 360-degree rotary brocade big fiber, the lifting rope A is always straightened under the action of the lifting heavy bar, so that lifting acting force of a lifting machine borne by the lifting head can be effectively applied to the movable pulley, and the synchronism of the stress of the movable pulley and the stress and the action of the lifting head is maintained.
Fourth, the 360-degree rotary brocade big fiber provided by the invention has the advantages that the length of the lifting heavy bar is longer than the lifting stroke of the corresponding lifting head, so that the phenomenon that the action synchronism of the movable pulley and the lifting rope A is influenced due to interference between the bottom end of the lifted lifting heavy bar and the top of the adjacent lifting heavy bar which is not lifted due to shaking in the descending process is avoided.
Fifth, according to the 360-degree rotary brocade big fiber, slots corresponding to the lifting ropes B in the same group are all positioned in the corresponding operation slots of the group, so that the lifting ropes B are convenient to install, and the installation efficiency of the lifting ropes B is improved.
Sixth, the 360-degree rotary brocade big fiber provided by the invention has the advantages that the loop formed by the lifting rope C can not be wound in the lifting process due to the action of the horizontal cross rod, so that the normal weaving of the loom is ensured.
Drawings
Fig. 1 is a schematic front view of the present application.
Fig. 2 is an enlarged schematic view in partial cross-section at the location of the cross plate of the present application.
Detailed Description
As can be seen from fig. 1 to fig. 2, the invention comprises a pulling machine 1 fixed above a brocade weaving machine, a plurality of groups of pulling heads 2 are distributed in parallel at the bottom of the pulling machine 1, each group of pulling heads 2 is provided with two rows of pulling heads 2 with corresponding number and positions, the number and positions of each row of pulling heads 2 are respectively corresponding, the pulling heads 2 are respectively connected with the pulling machine 1 in an up-down movable way through a driving device, the bottom of each pulling head is respectively fixed with one end of a pulling rope A4, the other end of the pulling rope A4 is connected with a rotating shaft of the moving pulley 5, a transverse plate 9 fixed with the brocade weaving machine is arranged below the moving pulley 5, a plurality of pulling ropes B10 are fixed at the top of the transverse plate 9, the number and positions of the pulling ropes B10 are respectively corresponding to the moving pulley 5, one end of the pulling ropes B10 is fixed with the transverse plate 9, the other end of the pulling ropes B10 bypasses the moving pulley 5 and then downwards passes through a through hole 8 arranged on the transverse plate 9 and is fixed with a wire loop 11, the other end of the pulling rope C13 passes through the loop C13 to form a through hole 15, and a weight D is formed at the bottom of the end of the pulling rope D is fixed with a bottom of the pulling rope D15.
An insert 6 is fixed at one end of the lifting rope B10, and one end of the lifting rope B10 is matched and fixed with a slot 7 arranged on the top surface of the transverse plate 9 through the insert 6.
The lifting ropes B10 corresponding to the two rows of lifting heads 2 in the same group and the fixed ends of the transverse plate 9 are respectively positioned between the two rows of lifting ropes A4 in the group.
The transverse plate 9 is respectively provided with a strip-shaped operation notch 17 corresponding to each group of lifting heads 2, and the slots 7 corresponding to the lifting ropes B10 of the same group are all positioned in the corresponding operation notches 17 of the group.
The distances between the through holes 8 corresponding to the two adjacent rows of lifting ropes B10 are equal, and the distances between the through holes 8 corresponding to the two adjacent lifting ropes B10 in the same row are equal.
The middle part of the lifting rope A4 is provided with a lifting heavy bar 3, and the gravity center of the lifting heavy bar 3 and the lifting rope A4 connected with the lifting heavy bar 3 are on the same straight line.
The heights of all the lifting heavy strips 3 are the same, the lengths of all the lifting heavy strips 3 are the same, and the lengths of the lifting heavy strips 3 are larger than the lifting strokes of the corresponding lifting heads 2.
The top of the lifting rope D15 is fixed with a threading ring 11, one end of the lifting rope C13 sequentially passes through the threading ring 11 arranged at the bottom of the lifting rope B10 and the threading ring 11 arranged at the lifting rope D15 and then is connected with the other end to form a loop, and the warp passes through the threading ring 11 arranged at the top of the lifting rope D15.
The loop wires formed by each row of lifting ropes C13 are respectively penetrated with a horizontal cross rod 12, and two ends of the horizontal cross rod 12 are fixed on the brocade weaving machine.
The horizontal cross bar 12 is located at the upper part of the loop formed by the lifting rope C13.
The spaces between two adjacent rows of lifting ropes C13 are respectively equal.
When the lifting device is used, when a certain lifting head 2 of the lifting machine 1 is lifted upwards, the lifting rope A4 is driven to lift the movable pulley 5, one end of the lifting rope B10 connected with the lifting rope C13 is lifted upwards due to the action of the movable pulley 5, and the lifting distance of the lifting rope B10 connected with the one end of the lifting rope C13 is twice as long as the lifting stroke of the lifting head 2 in the lifting stroke of the movable pulley 5 due to the action of the movable pulley 5; therefore, through the action of the movable pulley, the lifting amplitude and the lifting speed of the lifting rope C13 on the warp are improved, so that the rapid weaving of the brocade loom is ensured, and the weaving efficiency of the brocade is improved.
Meanwhile, compared with the connection position of the lifting rope B10 and the lifting rope C13, the lifting rope B is positioned at the axle center of the movable pulley 5 at the force applying position, namely, the lifting rope B10 is connected with one end of the lifting rope C13, and the lifting rope does not pass through the straight line where the lifting rope C13 is positioned, so that the acting force applied to the movable pulley 5 for lifting the one end of the lifting rope B connected with the lifting rope C13 can generate torque on one end of the lifting rope B10 connected with the lifting rope C13, so that when the lifting rope C13 is opposite to the lifting rope C13, the lifting rope C13 can move upwards and the end contacted with the lifting rope C13 also has a tendency to deviate to the side of the fixed end of the transverse plate 9, but the relative movement is not generated because the penetrating ring 11 at present contacted with the bottom end of the lifting rope C13 and the lifting rope B10 still has the effect of static friction force; when the lifting head 2 is lifted up to the highest stroke, the wire-threading ring 11 at the bottom end of the lifting rope B10 stops moving upwards, the lifting rope C13 continues to move upwards due to inertia, so that the lifting rope C13 is not contacted with the wire-threading ring 11 temporarily, the bottom of the lifting rope C13 and the lifting rope D15 are in a free state, and the top of a loop formed by the lifting rope C13 moves towards the fixed end side of the corresponding lifting rope B10 and the transverse plate 9 until the lifting rope C13 is contacted with the wire-threading ring 11 of the lifting rope B10 again under the action of the heavy hammer rod 16 and the lifting rope D15 due to the fact that the lifting rope C13 is always acted by torque of lifting acting force and no static friction force exists at the moment. Therefore, the loop wire formed by the lifting rope C13 can rotate relatively to the lifting rope B10 at the tail end of each lifting stroke, and further, in the adjacent two lifting processes, the contact stress positions of the lifting rope C13 relative to the lifting rope B10 are different, and correspondingly, the contact stress positions of the lifting rope C13 relative to the lifting rope D15 are also different. In the actual production process, the lifting rope C13 is used as consumable materials, the strength of the lifting rope C13 is lower than that of the lifting rope B10 and the lifting rope D15 connected with the lifting rope C13, and the lifting rope C13 is worn and broken after the weaving time is long; at this time, the machine is stopped and the lifting rope C13 is replaced; because more warp threads are used in the brocade weaving process, one warp thread corresponds to one lifting rope C13, the service lives of the lifting ropes C13 are slightly different, if one lifting rope C13 is broken, the machine is stopped for replacement, and because the number of the lifting ropes C is more, the lifting ropes C13 are required to be replaced frequently, so that the weaving of a loom is seriously affected; it is therefore generally known that when one of the lifting cords C13 breaks, although the other lifting cords C13 do not break, there is certainly a different degree of wear, and there are many to break, and in fact, it takes a lot of time to replace all the lifting cords C13 of the loom, so it is desirable for those skilled in the art to increase the service life of the lifting cords C13 as much as possible in order to reduce the number of times of replacing the lifting cords C13. Through the technical scheme of this application to make the atress position dispersion of lifting rope C13, be difficult for the fracture, prolonged lifting rope C13's life.
Claims (8)
1. 360 big fine structure of degree rotation type brocade, its characterized in that: including being fixed in the lifting machine (1) of brocade loom top, the bottom parallel distribution of lifting machine (1) has multiunit pull head (2), and every group pull head (2) are two rows of quantity and the corresponding pull head (2) of position, and quantity and the position of every row of pull head (2) are corresponding respectively, pull head (2) are connected with lifting machine (1) through drive arrangement from top to bottom swing joint respectively, the bottom of pull head is fixed with one end of lifting rope A (4) respectively, the other end and the pivot of movable pulley (5) of lifting rope A (4) are connected, the below of movable pulley (5) is equipped with diaphragm (9) fixed with the brocade loom, the top of diaphragm (9) is fixed with many lifting ropes B (10), the quantity and the position of lifting rope B (10) correspond respectively with movable pulley (5), one end and diaphragm (9) of lifting rope B (10) are fixed, the other end of lifting rope B (10) is passed through movable pulley (5) and is fixed with one end of lifting rope A (4) respectively, the other end is connected with one end that forms through-hole C (13) that forms through the wire loop (13) that is fixed with the fixed through the wire loop (13) of lifting rope C through the movable wire (13), a heavy hammer rod (16) is fixed at the bottom of the lifting rope D (15),
an insert (6) is fixed at one end of the lifting rope B (10), one end of the lifting rope B (10) is matched and fixed with a slot (7) arranged on the top surface of the transverse plate (9) through the insert (6),
the distances between the through holes (8) corresponding to the two adjacent rows of lifting ropes B (10) are equal, and the distances between the through holes (8) corresponding to the two adjacent lifting ropes B (10) in the same row are equal.
2. A 360 degree rotary brocade macrofiber structure as defined in claim 1, wherein: the lifting ropes B (10) corresponding to the two rows of lifting heads (2) in the same group and the fixed ends of the transverse plates (9) are respectively positioned between the two rows of lifting ropes A (4) in the group.
3. A 360 degree rotary brocade macrofiber structure as defined in claim 2, wherein: the transverse plate (9) is respectively provided with a strip-shaped operation notch (17) corresponding to each group of lifting heads (2), and the slots (7) corresponding to the lifting ropes B (10) of the same group are all positioned in the corresponding operation notches (17) of the group.
4. A 360 degree rotary brocade macrofiber structure as defined in claim 1, wherein: the middle part of the lifting rope A (4) is provided with a lifting heavy bar (3), and the gravity center of the lifting heavy bar (3) and the lifting rope A (4) connected with the lifting heavy bar (3) are on the same straight line.
5. A 360 degree rotary brocade macrofiber structure as defined in claim 4, wherein: the heights of all the lifting heavy strips (3) are the same, the lengths of all the lifting heavy strips (3) are the same, and the lengths of the lifting heavy strips (3) are larger than the lifting strokes of the corresponding lifting heads (2).
6. A 360 degree rotary brocade macrofiber structure as defined in claim 1, wherein: the wire loop (11) is fixed on the top end of the lifting rope D (15), one end of the lifting rope C (13) sequentially penetrates through the wire loop (11) arranged at the bottom of the lifting rope B (10) and the wire loop (11) arranged on the lifting rope D (15) and then is connected with the other end to form a loop, and the warp threads penetrate through the wire loop (11) arranged on the top end of the lifting rope D (15).
7. A 360 degree rotary brocade macrofiber structure as defined in claim 1, wherein: one end of the lifting rope D (15) is fixed at the top of the heavy hammer rod (16), the other end of the lifting rope D (15) penetrates through a loop formed by the lifting rope C (13) and then is fixed with the top of the heavy hammer rod (16) to form a semi-loop, and warp threads penetrate through the bottom of the loop formed by the lifting rope C (13) and the top of the semi-loop formed by the lifting rope D (15) respectively.
8. A 360 degree rotary brocade macrofiber structure as defined in claim 1, wherein: the loop wires formed by each row of lifting ropes C (13) are respectively penetrated with a horizontal cross rod (12), and two ends of the horizontal cross rods (12) are fixed on the brocade weaving machine.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201811611627.5A CN109440254B (en) | 2018-12-27 | 2018-12-27 | 360-degree rotary brocade big fiber structure |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201811611627.5A CN109440254B (en) | 2018-12-27 | 2018-12-27 | 360-degree rotary brocade big fiber structure |
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| Publication Number | Publication Date |
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| CN109440254A CN109440254A (en) | 2019-03-08 |
| CN109440254B true CN109440254B (en) | 2024-03-01 |
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| Application Number | Title | Priority Date | Filing Date |
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| CN201811611627.5A Active CN109440254B (en) | 2018-12-27 | 2018-12-27 | 360-degree rotary brocade big fiber structure |
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| CN (1) | CN109440254B (en) |
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US6148640A (en) * | 1998-08-03 | 2000-11-21 | Johns Manvill International, Inc. | Method for making chopped fiber |
| JP2004188869A (en) * | 2002-12-12 | 2004-07-08 | Toyota Industries Corp | Filament bundle pulling-out device in filament winding apparatus |
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| CN109440254A (en) | 2019-03-08 |
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