CN219653232U - Annular inlet wire mechanism of cold-proof surface fabric - Google Patents

Abstract

The utility model relates to an annular inlet wire mechanism of a thermal fabric. It has solved the unreasonable technical problem of current weaving machine inlet wire design. This annular inlet wire mechanism of cold-proof surface fabric still includes: the upper end of the textile rack is provided with at least one wire inlet hole; the rotary adjusting frame is arranged at the upper end of the textile machine frame and is provided with an outer annular platform and an inner annular platform which are radially arranged at intervals, and the rotary adjusting frame is connected with a rotary driving mechanism; the yarn winding device comprises a yarn winding drum, at least two outer annular platforms, a yarn winding device and a yarn winding device, wherein the yarn winding drum is provided with at least two rotating installation frames which are circumferentially arranged at the lower end of the outer annular platforms; the incoming wire guiding device is provided with at least two groups and is arranged in one-to-one correspondence with the coil barrels. The annular wire inlet mechanism of the thermal fabric is high in automation degree, high in yarn routing accuracy and not easy to wind, and the working efficiency is further improved.

Description

Annular inlet wire mechanism of cold-proof surface fabric

Technical Field

The utility model belongs to the technical field of textile manufacturing, and relates to an annular inlet wire mechanism of a thermal fabric.

Background

At present, most of thermal underwear is blended, and few single materials are adopted, and common fabrics comprise cotton, acrylic fibers, polyester fibers, modal fibers, viscose fibers and the like. Different fibers have different advantages, the first fabric is mainly seen when the underwear is purchased, and the more the components of the fabric are, the more the underwear is close to the advantages of the material, such as moisture absorption and air permeability, static resistance, elasticity, close fit and heat retention.

For example, chinese patent literature discloses a tension control mechanism [202220867327.9] of a rapier loom for producing polyester fabric, which comprises a bottom plate and a wire feeding rapier movably mounted on the bottom plate, wherein the bottom plate is provided with two wire feeding mechanisms, a tension bracket is fixedly mounted on the bottom plate and between the two wire feeding mechanisms, movable grooves are formed in the inner walls of the two sides of the tension bracket, and dismounting doors are arranged on the two sides of the tension bracket. This production polyester fabric's rapier weaving machine's tension control mechanism alternates tension bracket and inserted block through the locking lever, simultaneously, overlap on the inserted bar through the lantern ring, when changing the spring, only need open the dismouting door, take out the locking lever afterwards, can pull down elastic component from tension bracket and tension roller subassembly, direct change, its convenient operation is very simple, secondly, because interior roller rotates the relation of being connected with outer roller, the outer roller can autorotate for reducing frictional force when the yarn passes the outer roller, thereby the effectual wearing and tearing to the yarn that have reduced, the current textile machine production of cold-proof surface fabric adopts the yarn feed cylinder material loading of predetermineeing generally, but have the fabrics of multiple batch difference in the long-term production process, when need changing different material yarn feed cylinder, manual replacement and debug after the shut down, it is time consuming and laborious, production efficiency is low. The technical scheme does not solve the problem that the textile machine is preset to be produced, and the production efficiency has a larger lifting space.

Disclosure of Invention

The utility model aims to solve the problems in the prior art and provides an annular inlet wire mechanism for a thermal fabric.

The aim of the utility model can be achieved by the following technical scheme:

the annular inlet wire mechanism of cold-proof surface fabric includes:

the upper end of the textile rack is provided with at least one wire inlet hole;

the rotary adjusting frame is arranged at the upper end of the textile machine frame and is provided with an outer annular platform and an inner annular platform which are radially arranged at intervals, and the rotary adjusting frame is connected with a rotary driving mechanism;

the yarn winding device comprises a yarn winding drum, at least two outer annular platforms, a yarn winding device and a yarn winding device, wherein the yarn winding drum is provided with at least two rotating installation frames which are circumferentially arranged at the lower end of the outer annular platforms;

the wire inlet guide device is provided with at least two groups and is in one-to-one correspondence with the winding drums, and comprises two clamping conveying rollers which are vertically symmetrical on the inner annular platform and are positioned above the corresponding feeding holes, a conveying driving mechanism for driving the clamping conveying rollers to rotate, and a front guide wheel which is arranged on the inner annular platform and is positioned between the winding drums and the clamping conveying rollers, wherein one end of a yarn of each winding drum stretches out and sequentially passes through the front guide wheel and the clamping conveying rollers.

Further, the height of the outer annular platform is higher than the height of the inner annular platform.

Further, the clamping conveying roller is provided with wire grooves which are circumferentially arranged along the outer wall of the clamping conveying roller and axially arranged at intervals.

Further, one side of the autorotation mounting frame, which is close to the inner annular platform, is provided with an incoming line limiting ring.

Further, the rotation mounting frame is provided with a rotation driving mechanism connected with the coil cylinder.

Further, the rotation mounting frame comprises any one of a vertical mounting frame and a horizontal mounting frame.

Further, a negative pressure cavity communicated with the wire inlet hole is formed in the inner wall of the wire inlet hole, and the negative pressure cavity is connected with an air pump.

Further, a clamping part which penetrates radially is arranged in the wire inlet hole, and the clamping part is connected with a clamping driving mechanism.

Compared with the prior art, the annular wire inlet mechanism of the thermal fabric is high in automation degree, the conveying driving mechanism and the autorotation driving mechanism are arranged to respectively control the wire outlet speed of the winding cylinder end and the wire outlet speed of the clamping conveying roller end, so that the wire outlet of the yarn is kept in a straight state, the wire feeding accuracy of the yarn is high, the yarn is not easy to wind, the required yarn is in a preset clamping state, and the rotating adjusting frame is driven by the rotating driving mechanism only to realize the rapid adjustment and the production of the winding cylinders of different yarns, so that the working efficiency is further improved.

Drawings

Fig. 1 is a schematic structural view of an annular inlet wire mechanism of a thermal fabric.

Fig. 2 is a schematic view of a drum of the endless feed mechanism for thermal fabric of fig. 1.

Fig. 3 is a schematic view of an inlet wire guide device of the annular inlet wire mechanism of the thermal fabric of fig. 1.

Fig. 4 is a second schematic view of an embodiment of the endless loop yarn feeding mechanism of the thermal fabric of fig. 1.

Fig. 5 is a three schematic views of an embodiment of the endless loop yarn feeding mechanism of the thermal fabric of fig. 1.

In the figure, 10, a textile machine frame; 11. a wire inlet hole; 20. rotating the adjusting frame; 21. an outer annular platform; 22. an inner annular platform; 23. a rotary driving mechanism; 30. a coil barrel; 31. self-rotating mounting frame; 32. a wire inlet limit ring; 33. a rotation driving mechanism; 40. the incoming line guiding device; 41. clamping the conveying roller; 42. a conveying driving mechanism; 43. leading guide wheels; 44. a wire groove; 50. a negative pressure chamber; 51. an air extracting pump; 60. a clamping part; 61. clamping the driving mechanism.

Detailed Description

Example 1

Please refer to fig. 1 to 3, which are schematic structural diagrams of an annular inlet mechanism for thermal fabric provided by the present utility model. This annular inlet wire mechanism of cold-proof surface fabric still includes: a textile machine frame 10; a rotary adjusting frame 20 provided at an upper end of the textile machine frame 10; a coil cylinder 30 provided on the rotation adjusting frame 20; and an incoming wire guide 40 provided on the rotary adjusting frame 20. It is conceivable that the annular yarn feeding mechanism for thermal fabric further includes other functional components and specific structures, such as a spinning device, a cutting device, a mounting structure, a control component and the like in the textile machine frame 10, which are all known technologies to those skilled in the art, so they will not be described in detail herein.

The upper end of the textile machine frame 10 is provided with at least one feed hole 11, in this embodiment the feed hole 11 is arranged at the edge position of the textile machine frame 10. The yarn enters the textile frame 10 through the wire inlet hole 11, so that the textile process can be performed, the textile machine is in the prior art, and the specific working principle of the textile machine is not described herein.

The upper end of the textile machine frame 10 is provided with a rotary driving mechanism 23, the rotary driving mechanism 23 is connected with the rotary adjusting frame 20 and can drive the rotary adjusting frame 20 to rotate, and the rotary adjusting frame 20 is respectively provided with an outer annular platform 21 and an inner annular platform 22 which are arranged at radial intervals. In the present embodiment, the height of the outer annular platform 21 is higher than that of the inner annular platform 22, so that a larger installation space and routing angle are provided between the outer annular platform 21 and the inner annular platform 22, and installation interference and routing winding are avoided.

At least two rotation mounting frames 31 are arranged at intervals on the edge of the lower end of the outer annular platform 21, and the rotation mounting frames 31 can be fixedly connected with the outer annular platform 21. The rotation mounting frame 31 is provided with a rotating shaft, and the material rolling barrel 30 is sleeved on the rotating shaft on the rotation mounting frame 31, so that the material rolling barrel 30 can rotate from the shaft. The circumferential outer wall of each drum 30 can be wound with different yarns according to the weaving needs. When the spinning process is performed, the incoming line end of the yarn on the winding drum 30 stretches out continuously receives force to drive the winding drum 30 to rotate along with the winding drum, so that the yarn on the winding drum 30 is smoothly routed. The rotation mounting frame 31 is provided with a rotation driving mechanism 33 connected with the winding drum 30, and the rotation driving mechanism 33 is used for controlling the discharging speed of the winding drum 30, so that the problem of yarn inlet winding caused by the rotation inertia of the winding drum 30 is avoided.

One side of the rotation mounting frame 31, which is close to the inner annular platform 22, is provided with an inlet wire limiting ring 32, the inlet wire limiting ring 32 is fixed on the rotation mounting frame 31, and yarns on the winding cylinder 30 are discharged through the inlet wire limiting ring 32, so that the discharge positions of the yarns on the winding cylinder 30 are kept consistent.

The inner annular platform 22 is provided with at least two groups of wire inlet guide devices 40 which are arranged in one-to-one correspondence with the coil barrels 30, the wire inlet guide devices 40 comprise two clamping conveying rollers 41 which are vertically symmetrical on the inner annular platform 22 and positioned above corresponding feeding holes, a conveying driving mechanism 42 which drives the clamping conveying rollers 41 to rotate, and a front guide wheel 43 which is arranged on the inner annular platform 22 and positioned between the coil barrels 30 and the clamping conveying rollers 41, the wire inlet ends of yarns passing through the wire inlet limiting rings 32 are always in a straight line state after passing through the front guide wheel 43, and the wire inlet direction of the inclined angle is changed into a vertical direction and passes through the space between the two clamping conveying rollers 41. The distance between the clamping and conveying rollers 41 is smaller than the outer diameter of the yarn, and the conveying driving mechanism 42 drives the yarn feeding end of the clamping and conveying roller 41 to move downwards. More optimally, the clamping and conveying roller 41 is provided with wire grooves 44 which are circumferentially arranged along the outer wall of the clamping and conveying roller 41 and axially arranged at intervals, yarns passing through the clamping and conveying roller 41 are correspondingly clamped into the preset wire grooves 44, so that the wire outgoing direction of the clamping and conveying roller 41 is more accurate, and the yarns can accurately enter the wire incoming holes 11. It is conceivable that, during the pre-production, the yarn feeding end of each of the bobbins 30 is sequentially and correspondingly passed through the yarn feeding limit ring 32 and the front guide wheel 43, and the yarn is in a clamping and fixing state corresponding to the clamping and conveying roller 41; when the yarn is required to be produced, the yarn is driven to enter the wire inlet hole 11 by the clamping conveying roller 41 to realize textile production, and the rotary adjusting frame 20 can be driven to select the winding drums 30 with different yarn types.

In the present embodiment, the rotation driving mechanism 23, the conveyance driving mechanism 42, and the rotation driving mechanism 33 each employ a driving motor. The yarn outlet speeds of the winding cylinder 30 end and the clamping conveying roller 41 end are respectively controlled by the conveying driving mechanism 42 and the autorotation driving mechanism 33, so that yarn discharge is kept in a straight state, yarn running accuracy is high, winding is not easy to occur, required yarns are in a preset clamping state, and the rotating adjusting frame 20 is driven by the rotating driving mechanism 23, so that the winding cylinders 30 of different yarns are rapidly adjusted and put into production, and the working efficiency is further improved.

The rotation mounting frame 31 includes any one of a vertical mounting frame and a horizontal mounting frame, and in this embodiment, the rotation mounting frame 31 adopts a vertical mounting frame.

Example two

Referring to fig. 4, the structure and principle of the present embodiment are basically the same as those of the first embodiment, except that: the inner wall of the feed hole 11 is provided with a negative pressure cavity 50 communicated with the feed hole 11, and the negative pressure cavity 50 is connected with an air pump 51, and it is conceivable that in order to avoid the condition that the yarn is wound due to no fixation at the feed end of the yarn clamping the conveying roller 41, the yarn is accurately sucked into the feed hole 11 by generating negative pressure in the negative pressure cavity 50 through the air pump 51 in the feed hole 11.

Example III

Referring to fig. 5, the structure and principle of the present embodiment are basically the same as those of the second embodiment, and the only difference is that: the clamping part 60 which penetrates radially is arranged in the wire inlet hole 11, the clamping part 60 is connected with the clamping driving mechanism 61, and when the yarn inlet end enters the wire inlet hole 11, the clamping part 60 is driven by the clamping driving mechanism 61 to fix the yarn inlet end, so that the condition that the yarn in the wire inlet hole 11 is not fixed and the winding condition is caused is avoided.

The specific embodiments described herein are offered by way of example only to illustrate the spirit of the utility model. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions thereof without departing from the spirit of the utility model or exceeding the scope of the utility model as defined in the accompanying claims.

Claims (8)

1. The utility model provides a cold-proof surface fabric annular inlet wire mechanism which characterized in that, cold-proof surface fabric annular inlet wire mechanism includes:

the upper end of the textile rack is provided with at least one wire inlet hole;

the rotary adjusting frame is arranged at the upper end of the textile machine frame and is provided with an outer annular platform and an inner annular platform which are radially arranged at intervals, and the rotary adjusting frame is connected with a rotary driving mechanism;

the yarn winding device comprises a yarn winding drum, at least two outer annular platforms, a yarn winding device and a yarn winding device, wherein the yarn winding drum is provided with at least two rotating installation frames which are circumferentially arranged at the lower end of the outer annular platforms;

the wire inlet guide device is provided with at least two groups and is in one-to-one correspondence with the winding drums, and comprises two clamping conveying rollers which are vertically symmetrical on the inner annular platform and are positioned above the corresponding feeding holes, a conveying driving mechanism for driving the clamping conveying rollers to rotate, and a front guide wheel which is arranged on the inner annular platform and is positioned between the winding drums and the clamping conveying rollers, wherein one end of a yarn of each winding drum stretches out and sequentially passes through the front guide wheel and the clamping conveying rollers.

2. The endless loop inlet mechanism of thermal fabric of claim 1, wherein the outer annular platform is higher than the inner annular platform.

3. The annular wire inlet mechanism for the thermal fabric according to claim 1, wherein the clamping conveying roller is provided with wire grooves which are circumferentially arranged along the outer wall of the clamping conveying roller and axially arranged at intervals.

4. The annular inlet wire mechanism of thermal fabric according to claim 1, wherein an inlet wire limiting ring is arranged on one side of the autorotation mounting frame, which is close to the inner annular platform.

5. The annular inlet wire mechanism of thermal fabric according to claim 1, wherein the rotation mounting frame is provided with a rotation driving mechanism connected with the coil cylinder.

6. The endless loop inlet wire mechanism of claim 5, wherein the self-rotating mounting frame comprises either a vertical mounting frame or a horizontal mounting frame.

7. The annular inlet wire mechanism of the thermal fabric according to claim 1, wherein a negative pressure cavity communicated with the inlet wire hole is arranged on the inner wall of the inlet wire hole, and the negative pressure cavity is connected with an air pump.

8. The annular inlet wire mechanism for the thermal fabric according to claim 1 or 7, wherein a radially penetrating clamping part is arranged in the inlet wire hole, and the clamping part is connected with a clamping driving mechanism.