Core-spun woolen fabric weaving device
Technical Field
The invention relates to a knitting device and a knitted fabric of an artificial fur knitting machine, in particular to a core-spun woolen fabric, a knitting device of the core-spun woolen fabric and a preparation method of the core-spun woolen fabric.
Background
It is known that the conventional process for manufacturing woolen cloth fabric is to spin wool fibers into yarns and then to weave flat cloth with a loom, but when a man-made fur machine weaves core-spun woolen cloth fabric with a knitting needle, a core-spun woolen cloth fabric weaving device of the man-made fur machine can combine bottom yarns and wool fibers together to weave artificial fur cloth, replacing the conventional processing technology.
Fig. 1 to 7 are schematic structural diagrams of a conventional core-spun woolen fabric weaving device and a schematic structural diagram of a core-spun woolen fabric woven by the conventional core-spun woolen fabric weaving device, and the following first describes the main problems of the core-spun woolen fabric woven by the conventional core-spun woolen fabric weaving device.
As shown in fig. 1-3, when the core-spun woolen fabric weaving device of the artificial fur machine works, the woolen fibers are input to the sinker of the core-spun woolen fabric weaving device through the wool feeding device, a knitting needle 7 is arranged on one side of the head of the sinker, the knitting needle 7 comprises a needle rod 5 and a needle hook 11, the needle hook 11 is arranged on the head of the needle rod 5, a latch 2 is arranged on the lower portion of the needle hook 11, the latch 2 is rotatably connected with the needle rod 5 through a pin 8, the latch 2 can be turned over up and down around the pin 8, when the latch 2 is in a free state, the latch 2 is turned over downwards around the pin 8 under the action of gravity and falls down freely along the needle rod 5, at this time, the latch 2 completely opens the needle hook 11, when the needle hook 11 is opened, the woolen fibers can enter the inner area of the needle hook 11, when the latch 2 is turned over upwards around the pin 8, the latch 2 completely closes the needle hook 11, the woolen fibers 13 are hooked by the completely closed needle hook 11, and combining the bottom yarns 1 and the wool fibers together to complete the knitting of the wool loops.
However, when the existing weaving device for the core-spun woolen fabric of the artificial fur machine finishes the weaving of the plush loops, the needle cylinder 9 drives the sinker 3 to move horizontally when rotating, the needle cylinder 9 also drives the knitting needle 7 to move up and down, simultaneously, when the latch 2 moves up and down on the knitting needle 7, the latch 2 turns up and down around the pin shaft 8, when the latch 2 turns up and down around the pin shaft 8, the latch 2 opens and closes the hook 11 repeatedly, the hook 11 continuously weaves the plush fibers and the bottom yarns together, the weaved plush fibers 13 and the bottom yarns 1 form the plush loops 4 together, but when the existing latch 2 moves up and down, due to the effect of centrifugal force, the latch 2 is always in the state of turning up, so that the latch 2 leaves the needle bar 5, a large gap exists between the latch 2 and the lower half part of the needle bar 5, when the knitting needle 7 drives the needle bar 5 and the latch 2 to move down, a small amount of old plush fiber tails 6 enter the gap, the little pile fibers further lift the latch 2 to cause the latch 2 to turn over in advance, the latch 2 turns over in advance to cause more old pile loop fiber tails 6 to be blocked in a larger gap between the latch 2 and the lower half part of the needle bar 5, the old pile loop fiber tails 6 blocked in the larger gap between the latch 2 and the lower half part of the needle bar 5 cannot be picked up by the latch 2 and wrapped in the needle hook 11, the old pile loop fiber tails 6 which are not wrapped in the needle hook 11 cannot participate in the looping process of the new bottom yarn 1 and cannot be woven into the bottom gauze 100, the old pile loop fiber tails can only turn over to the back of the fabric along with the newly fed pile fibers 13 in the looping process and are hidden in the new pile loop 101, so that the height of the pile loops 101 woven by the pile fibers 13 and the new bottom yarn 1 cannot be reduced, the surface of the woven wool cloth is in a circular ring shape with obvious protrusions, and some pile fibers 13 and bottom yarn 101 woven by the pile fibers 1 leak on the outer surface of the wool cloth bottom gauze 100, some of the pile loops are leaked on the lower surface of the wool fabric bottom gauze 100, the quantity of the pile loops which are woven in the wool fabric bottom gauze 101 is small, the quantity of the pile loops which are leaked on the outer surface is large, the weaving density is low, the pile loops 101 which are leaked outside are easy to break and rub off, the surface is uneven, pilling is easy to occur, the pilling resistance is poor, the strength of the wool fabric cloth is low, the hand feeling is poor, and the quality is general.
Fig. 4 is a schematic structural diagram of a core-spun woolen fabric woven by a conventional core-spun woolen fabric weaving device, fig. 4 shows a woven base yarn cloth 100, the base yarn cloth 100 is formed by weaving and winding pile fibers 13 and a base yarn 1, the pile fibers 13 are continuously formed into a loop 101 after weaving, fig. 5 is an enlarged schematic diagram of one loop unit in fig. 4, and fig. 5 shows that the loop 101 of one weaving unit includes a loop start portion 102, a loop middle cladding winding portion 103 is formed in the middle section of the loop start portion 102, and a loop fiber tail portion 104 is formed at the tail portion of the loop 101.
In the prior art, when the latch 2 moves up and down, due to the action of centrifugal force, the latch 2 is often in an upward-turned state, all pile fibers 13 and ground yarns 1 cannot be completely wrapped and woven by the hook 11, after the pile fibers 13 are woven into a first pile loop 101, the wrapping and winding part 103 in the middle of the pile loop continues to participate in the second weaving, the pile fiber bundle of the subsequent pile loop 101 wraps the wrapping and winding part 103 in the middle of the pile loop, so that the height of the pile loop 101 of the subsequent pile loop 101 cannot be reduced, the pile loop 101 formed by the pile fibers 13 and the ground yarns 1 cannot be tightly attached to the surface of the woven ground gauze 100, a large number of pile loops 101 are leaked on the outer surface, the weaving density is low, after the pile fiber bundle is looped once, the redundant pile fiber tail part 103 wraps the ground yarns 1 to form a core-spun state, the pile fiber tail part 103 continuously participates in the weaving of the ground fabric with the ground yarns 1, so that the fiber tail part 103 leaks on the lower surface of the fabric, the terry 101 leaked on the upper surface and the terry fiber tail 103 on the lower surface are easily broken and abraded, the front and back surfaces of the fabric are easy to pilling, the pilling resistance is poor, and the hand feeling is poor.
Fig. 6 is a schematic diagram showing the shape of a fiber bundle unit in the core-spun woolen fabric woven by the existing core-spun woolen fabric weaving device, and it can be seen in fig. 6 that the fiber bundle of the woolen fiber 13 is not completely straightened together, but is in a fluffy and fluffy state, so that the woven fabric has an uneven surface, a rough surface and low strength.
Fig. 7 is a schematic structural diagram of a core-spun woolen fabric woven by a conventional core-spun woolen fabric weaving device, which can clearly see the shape distribution of a fiber bundle unit in the fabric, and the core-spun woolen fabric woven by the conventional core-spun woolen fabric weaving device is composed of all fiber bundle units with poor coating quality, and the surface of the whole core-spun woolen fabric is uneven due to the composition of the fiber bundle units with poor coating quality, so that the tensile strength is low, and the requirement of people on the high-quality core-spun woolen fabric cannot be met.
Disclosure of Invention
The invention provides a pile fiber cloth woven by a core-spun wool fabric weaving device of an artificial fur machine, aiming at the technical problems that the pile loop height of the pile fiber and a new bottom yarn woven by the existing pile fiber cloth woven by the core-spun wool fabric weaving device of the artificial fur machine cannot be reduced, the surface of the woven wool fabric is in a circular loop shape with obvious protrusions, some pile loops woven by the pile fiber and the bottom yarn are leaked on the outer surface of the wool fabric cloth, some pile loops are leaked on the lower surface of the wool fabric cloth, the pile loops are woven in the pile fiber cloth, the pile loops are more leaked on the outer surface, the weaving density is low, the pile loops leaked outside are easy to be broken and ground, the surface is uneven, the pile loops are easy to pilling, the anti-pilling capability is poor, the strength of the pile fiber cloth is low, the hand feeling is poor, and the quality is general, pile loops woven by pile fibers and bottom yarns are tightly attached to the outer surface of the woolen cloth and cannot leak to the lower surface of the woolen cloth, the number of the pile loops woven by the pile loops in the woolen cloth is large, the pile loops leaking to the outer surface are few, the weaving density is high, the pile loops tightly attached to the outer surface of the woolen cloth are not easy to break and break, the pile loops are not easy to abrade, the surface is flat, pilling is not easy to occur, the anti-pilling capability is high, the strength of the woolen cloth is high, the hand feeling is good, and the quality of the core-spun woolen fabric weaving device and the core-spun woolen fabric are stable.
Therefore, the core-spun woolen fabric comprises terry formed by base yarns and plush fibers, wherein the terry is tightly attached to the outer surface of the fabric, the middle section of the plush fibers forms a terry middle coating winding part, and the terry middle coating winding part and the base yarns are attached to the inside of the fabric together; the looped pile fiber tail part is formed by wrapping the tail part of the winding part in the middle of the looped pile, and the looped pile fiber tail part and the bottom yarn are continuously attached to the inside of the fabric.
The invention produces a core-spun woolen fabric knitting device of the above-mentioned core-spun woolen fabric, it has knitting needles, the knitting needle includes the needle bar, the upper portion of the needle bar has hooks and latch, the latch is connected with needle bar rotation through the axis pin, there are magnetic devices near the knitting needle, the magnetic device can make the latch turn over and close to one side of the needle bar downward; the magnetic device is arranged on the back of the knitting needle; the magnetic force lines of the magnetic device are distributed through the latch, the latch can be kept in a downward fully-opened state by the magnetic force generated by the magnetic force lines of the magnetic device, the opening formed by the latch and the hook is kept to the maximum, and the fiber bundles of the pile fibers for core-spun wool fabric can be completely wrapped in the opening formed by the latch and the hook.
Preferably, the distance of the magnetic means close to the needles is adjustable.
Preferably, the end face of the magnetic device close to the back face of the knitting needle has a mounting clearance of 0.5-2mm from the back face of the knitting needle.
Preferably, the magnetic means is a permanent magnet or an electromagnet.
Preferably, the permanent magnet is neodymium iron boron magnetic steel or alnico magnetic steel or samarium cobalt magnetic steel.
Preferably, the permanent magnet is cylindrical or rectangular or other shaped structure.
A preparation method of a core-spun woolen fabric comprises the following steps:
(1) pile fibers are fed into a core-spun wool fabric weaving device and are ready to be wound and woven with bottom yarns;
(2) the latch of the core-spun woolen fabric weaving device is turned downwards, the needle hook is opened, and the plush fibers are completely covered in the opened needle hook;
(3) the magnetic device of the core-spun woolen fabric weaving device attracts the latch, and the latch in a downward overturning state is tightly attached to one side of the needle rod, so that a large gap is prevented from being formed between the latch and the lower part of the needle rod, and a maximum opening angle is ensured to be formed between the latch and the needle hook;
(4) the knitting needle of the core-spun woolen fabric knitting device moves downwards, the needle latch overcomes the attraction of a magnetic device under the support of the looped old pile loop, and the pile fibers are completely wrapped inside the needle hook, so that the knitting of the pile fibers and the bottom yarns is completed;
(5) the terry formed by the plush fibers in the step (4) is tightly attached to the outer surface of the fabric, the middle section of the plush fibers forms a terry middle wrapping and winding part, and the terry middle wrapping and winding part and the bottom yarn are attached to the inside of the fabric together;
(6) in the step (5), the tail part of the winding part is coated in the middle of the terry to form a terry fiber tail part, and the terry fiber tail part and the bottom yarn are continuously attached to the inside of the fabric together;
(7) and (5) repeating the steps (1) to (6) to finish the production of the core-spun woolen fabric.
The invention has the advantages that because the magnetic device is arranged near the knitting needle, when the knitting device of the core-spun woolen fabric of the artificial fur machine weaves the woolen fiber cloth, the needle cylinder drives the sinker to move horizontally when rotating, the needle cylinder also drives the knitting needle to move up and down, meanwhile, when the latch moves up and down on the knitting needle, the latch turns over up and down around the pin shaft, when the latch turns over up and down around the pin shaft, the latch opens and closes the hook repeatedly, the latch of the knitting needle can be under the action of a magnetic field except the action of centrifugal force and keeps the state of turning over downwards, the latch can be always close to the needle rod, no gap exists between the latch and the needle rod, the woolen fiber can not be left in the gap between the latch and the needle rod, the latch is pushed to turn over upwards by the old woolen fiber, when the needle rod and the latch move downwards, no old woolen fiber tail is blocked under the latch, all the old woolen fiber tails are on the latch and all are covered by the hook, the fiber tails of the old looped piles are further close to the needle bar under the action of auxiliary blowing air flow generated by the air flow generator, and are woven into looped piles together with the bottom yarns, all the fiber tails of the old looped piles are coated on the newly fed bottom yarns and are woven into loops along with the new bottom yarns, the loops of the new looped piles are woven into the base fabric, the looping height of the new looped piles is not influenced, the new looped piles are adhered to the base fabric and are approximately flat, the wool fabric fibers cannot leak on the lower surface of the wool fabric, the looped piles woven in the wool fabric have more loops, the looped piles leaking on the outer surface are fewer, the weaving density is high, the looped piles tightly adhered to the outer surface of the wool fabric are not easy to break and wear off, the surface is flat, pilling is not easy to occur, the pilling resistance is high, the strength of the wool fabric is high, the hand feeling is good, and the quality is stable.
Drawings
Fig. 1 is a schematic structural diagram of a conventional core-spun woolen fabric weaving device (a state that a latch falls downward);
fig. 2 is a schematic structural diagram of a conventional core-spun woolen fabric weaving device (a state that a latch is covered upwards);
FIG. 3 is a schematic structural diagram of a conventional core-spun woolen fabric knitting device (a force state when a needle cylinder rotates and a latch is driven to move);
fig. 4 is a schematic structural diagram of a core-spun woolen fabric woven by a conventional core-spun woolen fabric weaving device;
FIG. 5 is an enlarged schematic view of one of the loop units of FIG. 4;
fig. 6 is a schematic shape diagram of a fiber bundle unit in a core-spun woolen fabric woven by a conventional core-spun woolen fabric weaving device;
fig. 7 is a schematic structural diagram of a core-spun woolen fabric woven by a conventional core-spun woolen fabric weaving device;
FIG. 8 is a schematic diagram of the distribution of magnetic lines of force of the magnetic device according to the embodiment of the present invention (latch falling downward);
FIG. 9 is a schematic view showing the distribution of magnetic lines of force (with the latch being covered upward) of the magnetic device according to the embodiment of the present invention;
FIG. 10 is a force analysis diagram of the magnetic device and latch according to an embodiment of the present invention;
fig. 11 is a schematic structural diagram of a core-spun woolen fabric woven by the core-spun woolen fabric weaving device according to the embodiment of the present invention;
FIG. 12 is an enlarged schematic view of one of the loop units of FIG. 11;
fig. 13 is a schematic shape diagram of a fiber bundle unit in a core-spun woolen fabric woven by the core-spun woolen fabric weaving device according to the embodiment of the invention;
fig. 14 is a schematic structural diagram of a core-spun woolen fabric woven by the core-spun woolen fabric weaving device according to the embodiment of the invention;
FIG. 15 is a schematic side view of a magnetic device mounting shaft according to an embodiment of the present invention;
FIG. 16 is a schematic top view of a magnetic device according to an embodiment of the present invention;
FIG. 17 is a schematic view of the distribution of the effective magnetic field area of a magnetic device according to an embodiment of the present invention;
FIG. 18 is a schematic front view of a magnetic device according to an embodiment of the present invention;
FIG. 19 is a schematic axial view of another direction of installation of a magnetic device in accordance with an embodiment of the present invention.
The symbols in the drawings illustrate that:
1. a bottom yarn; 2. a latch; 3. a sinker; 4. old terry; 5. a needle bar; 6. old looped pile fiber tails; 7. knitting needles; 8. a pin shaft; 9. a needle cylinder; 10. an airflow generator; 11. a needle hook; 12. a magnet; 13. pile fibers; 100. bottom gauze; 101. a pile loop; 102. a loop initiation portion; 103. the winding part is coated in the middle of the terry; 104. a looped pile fiber tail; 201. a mounting seat; 202. a magnet; 203. an upper triangle; 204. installing an adjusting hole; 205. a lower triangle.
Detailed Description
The present invention will be further described with reference to the following examples.
Examples
As shown in fig. 8-14, the core-spun woolen fabric includes a loop 101 formed by a bottom yarn 1 and a pile fiber, the loop 101 is tightly attached to the outer surface of the fabric, a loop middle wrapping winding part 103 is formed at the middle section of the pile fiber, and the loop middle wrapping winding part 103 is attached to the inside of the fabric together with the bottom yarn 1; the end of the looped pile intermediate covering winding part 103 forms a looped pile fiber end 104, and the looped pile fiber end 104 continues to be attached to the inside of the fabric together with the ground yarn 1.
Fig. 8 is a schematic view showing the distribution of magnetic lines of force after the magnetic device 202 is added to the core-spun woolen fabric knitting device of the present invention, the schematic view is a state diagram in which the latch 2 hangs down, it can be seen that the magnetic lines of force of the added magnetic device 202 are distributed through the latch 2, so that the magnetic force generated by the magnetic lines of force of the magnetic device 202 can keep the latch 2 in a state of being fully opened downward, the opening formed by the latch 2 and the hook 11 is kept maximum, the fiber bundles of the pile fibers 13 can be fully covered in the opening formed by the latch 2 and the hook 11, and at the same time, the latch 2 can be kept tightly attached to the surface of the needle bar 5 due to the magnetic force generated by the magnetic lines of force of the magnetic device 202, there is no gap between the latch 2 and the lower half part of the needle bar 5, the pile fibers 13 cannot enter the gap, the pile fibers 13 cannot be in a scattered state, and can be completely wound with the ground yarns 1, woven into a fabric.
Fig. 9 is a schematic view showing the distribution of magnetic lines of force of the magnetic means 202 when the latch 2 is in the state of covering upward, and when the knitting needle 7 moves downward, the latch 2 receives the upward lifting force of the old pile loop 4, and the latch 2 rolls up the pile fibers 13 covering the hook 11 together with the ground yarn 1 against the attractive force of the magnetic lines of force of the magnetic means 202, and completes the knitting of the pile loop 101.
Fig. 10 is a force analysis diagram of the magnetic device 202 and the latch 2, and it can be seen that, the magnetic field acting force T generated by the magnetic device 202 is related to the centrifugal force F generated by the latch 2 caused by the rotation of the needle cylinder 9 of the knitting needle 7, and the magnetic field acting force T overcomes the centrifugal force F to tightly abut the latch 2 on the needle bar 5 to form a stable open state, so that the latch 2 does not jump due to the action of the centrifugal force F, a stable open state can be formed, and the fiber bundle of the woolen cloth fiber 13 can be completely covered.
Fig. 11 is a schematic structural view of the core-spun woolen fabric woven by the core-spun woolen fabric weaving device of the present invention, in which it can be seen that the fiber bundles of the woolen fibers 13 and the loops 101 formed by the ground yarn 1 are uniformly arranged on the upper surface of the fabric, and the loops 101 are looped at a time without covering the fiber tail 104 of one loop, so that the loops 101 on the surface of the fabric are uniform in height and tightly cover the upper surface of the fabric; fig. 12 is an enlarged view of one of the loop units of fig. 11, and it can be seen that the loop 101 includes a loop start 102, and subsequent successive bundles of the loop start 102 form a loop intermediate cover wrap 103, and the loop intermediate cover wrap 103 engages the base yarn 1 for subsequent weaving, all within the fabric.
Fig. 13 is a schematic diagram of the shape of a fiber bundle unit in a core-spun woolen fabric woven by a core-spun woolen fabric weaving device in the fabric, due to the effective control of the magnetic device 202 on the movement of the latch 2, the fiber bundle of the wool pile fiber 13 is tightly wound with the ground yarn 1 to form a regular weave, without the quality problem of wool pile fiber disorder, fig. 14 is a schematic diagram of the structure of the core-spun woolen fabric woven by the core-spun woolen fabric weaving device, in which the uniform distribution state of the fiber bundle unit can be seen, all the fiber bundle units of the core-spun woolen fabric woven by the core-spun woolen fabric weaving device are uniform, and the surface of the woven fabric is flat.
Fig. 15-19 are schematic structural views of a core-spun woolen fabric weaving device according to the present invention, which is provided with a needle cylinder 9, an upper cam 203 is provided on an outer side of the needle cylinder 9, a sinker 3 is provided on the upper cam 203, a lower cam 205 is provided on a side surface of the needle cylinder 9 at a lower portion of the upper cam 203, a knitting needle 7 is provided on the lower cam 205, the knitting needle 7 includes a needle bar 5, a hook 11 and a latch 2 are provided on an upper portion of the needle bar 5, the latch 2 is rotatably connected to the needle bar 5 through a pin 8, a magnetic device 202 is provided near the knitting needle 7, the magnetic device 202 can generate a suction force on the latch 2, and the suction force can attract the latch 2 to turn downward and press close to one side of the needle bar 5; the magnetic device 202 is arranged on the back of the knitting needle 7 in the embodiment; the magnetic device 202 is arranged on the back surface of the knitting needle 7 and is arranged on the mounting seat 201, the mounting seat 201 is fixed on a rack or a lower triangle 203, the magnetic device 202 is adjustably fixed on the mounting seat 201, the mounting gap between the end surface of the magnetic device 202 close to the back surface of the knitting needle 7 and the up-down distance between the end surface of the magnetic device 202 close to the back surface of the knitting needle 7 and the latch 2 of the knitting needle 7 can be adjusted, the positioning position of the magnetic device 202 can be adjusted according to the size and shape difference of the knitting needle 7, the optimal magnetic force line distribution state is adjusted, and therefore the opening and the closing of the latch 2 can be stably controlled, and a stable knitting process is formed; through tests, the mounting gap between the end surface of the magnetic device 202 arranged on the back surface of the knitting needle 7, close to one side of the back surface of the knitting needle 7, and the back surface of the knitting needle 7 is 0.5-2mm, and the device can be suitable for core-spun woolen fabric weaving devices of various specifications.
The magnetic device 202 can also be a permanent magnet or an electromagnet, the permanent magnet is neodymium iron boron magnetic steel or aluminum nickel cobalt magnetic steel or samarium cobalt magnetic steel, the permanent magnet is cylindrical or rectangular, the magnetic device 202 in this embodiment is neodymium iron boron magnetic steel, and the shape of the magnetic device is approximately circular; the magnetic steel can adopt special-shaped structures, such as a sector structure, a triangle structure and an oval structure, so long as the working edge of the magnetic steel follows the track of the needle tongue and is farther away from the needle tongue, the effect that the needle tongue is turned downwards to be close to one side of the needle rod can be realized, and the effect can be realized by using the straight edge of the sector magnetic steel, the outer arc edge of the sector magnetic steel and the quadrilateral magnetic steel similar to a circle.
The preparation method of the core-spun woolen fabric comprises the following steps:
(1) feeding the wool fibers 13 into a core-spun wool fabric weaving device to be ready for winding and weaving with the bottom yarns 1;
(2) the latch 2 of the core-spun woolen fabric weaving device is turned downwards, the needle hook 11 is opened, and the plush fibers 13 are completely covered in the opened needle hook 11;
(3) the magnetic device 202 of the core-spun woolen fabric weaving device attracts the latch 2, tightly attaches the latch 2 in a downward overturning state to one side of the needle bar 5, avoids a large gap between the latch 2 and the lower part of the needle bar 5, and ensures that a maximum opening angle is formed between the latch 2 and the needle hook 11;
(4) the knitting needle 7 of the core-spun woolen fabric knitting device moves downwards, the latch 2 overcomes the attraction of the magnetic device 202 under the support of the looped old looped pile 101, and the pile fibers 13 are completely wrapped inside the needle hook 11, so that the knitting of the pile fibers 13 and the bottom yarns 1 is completed;
(5) the terry 101 formed by the plush fibers in the step (4) is tightly attached to the outer surface of the fabric, the middle section of the plush fibers 13 forms a terry middle wrapping and winding part 103, and the terry middle wrapping and winding part 103 and the bottom yarn 1 are attached to the inside of the fabric together;
(6) in the step (5), the tail part of the winding part 103 is coated in the middle of the looped pile to form a looped pile fiber tail part 104, and the looped pile fiber tail part 104 and the bottom yarn 1 are continuously attached to the inside of the fabric;
(7) and (5) repeating the steps (1) to (6) to finish the production of the core-spun woolen fabric.
When the core-spun woolen fabric weaving device works, because the magnetic device 202 is arranged on the back of the knitting needle 7, when the core-spun woolen fabric weaving device weaves woolen fiber cloth, the needle cylinder 9 drives the sinker 3 to move horizontally when rotating, the needle cylinder 9 also drives the knitting needle 7 to move up and down, meanwhile, when the latch 2 moves up and down on the knitting needle 7, the latch 2 turns up and down around the pin shaft 8, when the latch 2 turns up and down around the pin shaft 8, the latch 2 repeatedly opens and closes the needle hook 11, the latch 2 of the knitting needle 7 can be under the action of a magnetic field except the action of centrifugal force, keeps the state of turning down, the latch 2 is always close to the needle bar 5, no gap exists between the latch 2 and the needle bar 5, the woolen fiber 13 cannot be left in the gap between the latch 2 and the needle bar 5, the latch 2 is pushed by the old woolen loop 4 to turn up, when the needle bar 5 and the latch 2 move down, the tail of the old woolen fiber 4 is not blocked under the latch 2, all the fiber tails of the old looped piles 4 are arranged on the needle tongues 2 and are completely wrapped by the needle hooks 11, the fiber tails of the old looped piles 4 are further close to the needle bars 5 under the action of auxiliary blowing air flow generated by the air flow generator 10 and are woven into looped piles 101 together with the bottom yarns 1, all the fiber tails of the old looped piles 4 are wrapped on the newly fed bottom yarns 1 and are woven into loops together with the new bottom yarns 1, the loops are woven into the bottom gauze 100 without influencing the looping height of the new looped piles 101, the new looped piles 101 are adhered to the bottom gauze 100 and are in an approximately flat cloth shape, wool fibers 13 cannot leak on the lower surface of the wool cloth, the looped piles 101 are woven in the wool fiber cloth, the number of loops which leak on the outer surface is small, the weaving density is high, the looped piles 101 adhered to the outer surface of the wool cloth are not easy to be pulled apart and are not easy to be ground apart, the surface is flat, the pilling resistance is high, the plush fiber cloth has high strength, good hand feeling and stable quality.
After the fiber bundles of the wool fabric fibers 13 are knitted into the terry 101, the fiber bundle starting part of the wool fabric fibers 13 forms a terry starting part 102, redundant wool fabric fibers 13 form a terry middle covering winding part 103, the terry middle covering winding part 103 continuously participates in the knitting of the base fabric, as the wool fabric fibers 13 are completely covered by the needle hooks 11, the terry starting part 102 is tightly wound with the bottom yarn 1, a high terry 101 cannot be formed on the upper surface of the fabric, meanwhile, the terry middle covering winding part 103 is continuously wound with the bottom yarn 1, the subsequent knitting is completed, the terry middle covering winding part 103 forms multiple bends in the base fabric, the wool fibers 13 of the terry middle covering winding part 103 rub and self-lock in the base fabric, the wool fibers 13 are not easy to be pulled out, the knitted fabric has good anti-pilling resistance, and reaches 4 grades through actual tests, while the knitting method of the existing device is not as large as 3 grades, some require the addition of an anti-pilling aid before grade 3 can be achieved.
The fiber bundle of the pile fibers 13 wraps the ground yarn 1 in a wrapping state, which is equivalent to a core-spun yarn, and the ground yarns of the fabric are wrapped inside, so that the fabric has good hand feeling, the thickness and the rigidity of the base fabric are increased, and the drapability of the fabric is correspondingly changed; the redundant fibers after the pile fibers 13 are looped participate in the base fabric weaving, so that the strength of the base fabric can be enhanced, and the use ratio of the base yarn 1 can be reduced.
The 13 pile fiber bundles do not form the pile loops 103 twice, the looping height of the next fiber bundle cannot be influenced, the height of the pile loops on the back of the woven fabric is extremely low, the pile loops 103 on the front of the fabric are clear through testing and are generally 1-2mm high, and the fabric effect is similar to that of a woolen sweater.
Two surfaces of the fabric are both fluffy fibers, when the fabric is used for multi-layer composite use, glue is easy to permeate, the fibers directly contact with the glue, and bonding is firmer.
The fabric can be woven by multicolor jacquard at will, and the fabric with more than three colors still keeps the same lightness and thinness as plain yarn dyed fabric. The multicolor jacquard weaving of the traditional woolen sweater, woolen cloth and other knitted fabrics is thicker than plain color fabrics, and the thicker and harder the fabric is, the more colors are.
Because the spinning process is not carried out in advance, loose fibers directly cover the core with the bottom yarn 1 and directly participate in weaving, the whole process flow is shortened, and energy is saved and consumption is reduced. The production cycle of the product is short, and the method is suitable for small-batch fast-paced personalized production.
However, the above description is only exemplary of the present invention, and the scope of the present invention should not be limited thereby, and the replacement of the equivalent components or the equivalent changes and modifications made according to the protection scope of the present invention should be covered by the claims of the present invention.