CN112609362A

CN112609362A - Efficient single yarn sizing machine

Info

Publication number: CN112609362A
Application number: CN202011551036.0A
Authority: CN
Inventors: 施金星
Original assignee: Suzhou Yixia Textile Technology Co ltd
Current assignee: Suzhou Yixia Textile Technology Co ltd
Priority date: 2020-12-24
Filing date: 2020-12-24
Publication date: 2021-04-06

Abstract

The invention relates to the field of sizing machines, in particular to a high-efficiency single-yarn sizing machine. The sizing machine comprises a machine table, a passive yarn winding drum positioning mechanism, a first guide roller mechanism, a sizing chamber, a drying chamber, a second guide roller mechanism, a driving yarn winding drum positioning mechanism, a winding drum distance adjusting mechanism, a winding drum rotating mechanism, an immersion roller, a cam swinging mechanism, a cam lifting mechanism, a sizing brush, a sizing pool and a heating rod. The invention positions the yarn bobbin through the passive yarn winding bobbin positioning mechanism and the active yarn winding bobbin positioning mechanism. The distance between the two yarn drums is adjusted by the yarn take-up drum distance adjusting mechanism. The submerged roller is driven by a cam lifting mechanism to press the yarn into the slurry tank for sizing. The slurry is agitated by oscillating the submerged roller back and forth by a cam oscillating mechanism. And (4) uniformly scraping the slurry on the yarns through a slurry brush. This application has improved the efficiency of yarn starching.

Description

Efficient single yarn sizing machine

Technical Field

The invention relates to the field of sizing machines, in particular to a high-efficiency single-yarn sizing machine.

Background

After the fiber is spun into yarn, the strength is low, the hairiness is more, the weaving requirement cannot be met, and the yarn needs to be sized in order to improve the strength of the yarn, reduce the hairiness, reduce the surface friction force of the yarn and reduce the friction. However, the existing yarn sizing equipment has single function and low sizing efficiency.

Disclosure of Invention

To solve the technical problems described in the background art, the present invention provides an efficient single yarn sizing machine. The yarn bobbin is positioned by the passive yarn winding bobbin positioning mechanism and the active yarn winding bobbin positioning mechanism. The distance between the two yarn drums is adjusted by the yarn take-up drum distance adjusting mechanism. The submerged roller is driven by a cam lifting mechanism to press the yarn into the slurry tank for sizing. The slurry is agitated by oscillating the submerged roller back and forth by a cam oscillating mechanism. And (4) uniformly scraping the slurry on the yarns through a slurry brush. This application has improved the efficiency of yarn starching.

The technical scheme adopted by the invention for solving the technical problems is as follows:

an efficient single yarn sizing machine comprises a machine table, a passive yarn winding drum positioning mechanism, a first yarn guide roller mechanism, a sizing chamber, a drying chamber, a second yarn guide roller mechanism, an active yarn winding drum positioning mechanism, a winding drum distance adjusting mechanism, a winding drum rotating mechanism, an immersion roller, a cam swinging mechanism, a cam lifting mechanism, a slurry brush, a slurry pool and a heating rod, wherein the machine table is sequentially provided with the passive yarn winding drum positioning mechanism, the first yarn guide roller mechanism, the sizing chamber, the drying chamber, the second yarn guide roller mechanism and the active yarn winding drum positioning mechanism, the machine table is internally fixed with the winding drum distance adjusting mechanism and the winding drum rotating mechanism, the passive yarn winding drum positioning mechanism is connected on a horizontal linear guide rail of the machine table in a sliding manner, the bottom of the passive yarn winding drum positioning mechanism is fixed on a sliding seat of the winding drum distance adjusting mechanism, the active yarn winding drum positioning mechanism is fixed on an output shaft of the winding drum, the sizing chamber is fixed with a cam lifting mechanism, a piston rod of the cam lifting mechanism is fixed on a cam swing mechanism, the cam swing mechanism is connected with a cam, the cam is fixedly connected with a connecting plate, the connecting plate is rotatably connected with an immersion roller, the bottom of the cam swing mechanism is fixed with a sizing brush, a sizing tank is arranged in the sizing chamber, and a heating rod is fixed in an interlayer of a bottom plate of the sizing tank.

Specifically, the passive yarn winding drum positioning mechanism comprises a base, an upper seat, a top plate and a top plate lifting cylinder, wherein a first shaft rod is fixed on the bottom surface of the top plate, a second shaft rod is fixed on the upper plane of the upper seat, the first shaft rod and the second shaft rod are coaxial and have the same diameter, the upper seat is rotatably connected to the base through a shaft, the base is connected to a machine table in a sliding fit mode, and the base is fixed to a sliding seat of a winding drum distance adjusting mechanism.

Specifically, the first wire guide roller mechanism and the second wire guide roller mechanism are both composed of a lifting linear module, a width adjusting seat, an upper wire guide roller and a lower wire guide roller, a cylinder body of the lifting linear module is fixed on a machine table, the width adjusting seat is fixed on a sliding seat of the lifting linear module, and the upper wire guide roller and the lower wire guide roller are respectively and rotatably connected onto two sliding seats of the width adjusting seat;

the width adjusting seat is composed of a seat body, sliding seats, a positive and negative thread screw rod and a motor, the motor is fixed on the seat body, the positive and negative thread screw rod is rotatably connected to the seat body, one end of the positive and negative thread screw rod is fixed on an output shaft of the motor, ball nuts are respectively in threaded connection with a positive thread section and a negative thread section of the positive and negative thread screw rod, the two ball nuts are respectively fixed on the two sliding seats, and the two sliding seats are connected to the seat body in a sliding fit.

Specifically, the active yarn winding drum positioning mechanism is a chuck which is fixed on an output shaft of a winding drum rotating mechanism, and the winding drum rotating mechanism is a motor.

Specifically, the take-up drum distance adjustment mechanism is a horizontal linear module.

Specifically, the cam swing mechanism comprises a box body, a rack, a single-rod cylinder, a shaft and a gear, the box body is fixed on a piston rod of the cam lifting mechanism, the shaft is fixed on the cam, the cam is rotatably connected to the box body through the shaft, the gear is fixed on the shaft of the cam, the single-rod cylinder is fixed in the box body, the rack is fixed on a piston rod of the single-rod cylinder, and the rack is meshed with the gear.

Specifically, the cam lifting mechanism is an air cylinder.

Specifically, the two ends of the opening of the slurry tank are respectively and rotatably connected with a guide wheel.

The invention has the beneficial effects that: the invention provides an efficient single yarn sizing machine. The yarn bobbin is positioned by the passive yarn winding bobbin positioning mechanism and the active yarn winding bobbin positioning mechanism. The distance between the two yarn drums is adjusted by the yarn take-up drum distance adjusting mechanism. The submerged roller is driven by a cam lifting mechanism to press the yarn into the slurry tank for sizing. The slurry is agitated by oscillating the submerged roller back and forth by a cam oscillating mechanism. And (4) uniformly scraping the slurry on the yarns through a slurry brush. This application has improved the efficiency of yarn starching.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of the passive yarn take-up spool positioning mechanism of the present invention;

in the figure, 1, a machine table, 2, a passive yarn winding drum positioning mechanism, 3, a guide roller mechanism I, 4, a sizing chamber, 5, a drying chamber, 6, a guide roller mechanism II, 7, an active yarn winding drum positioning mechanism, 8, a winding drum distance adjusting mechanism, 9, a winding drum rotating mechanism, 10, an immersion roller, 11, a cam, 12, a cam swinging mechanism, 13, a cam lifting mechanism, 14, a size brush, 15, a size pool, 16, a heating rod, 17, a guide wheel, 21, a base, 22, an upper layer seat, 23, a top plate, 24, a top plate lifting cylinder, 61, a lifting linear module, 62, a width adjusting seat, 63, an upper guide roller, 64, a lower guide roller, 121, a box body, 122, a rack and 123 are single-rod cylinders.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

Fig. 1 is a schematic structural view of the present invention, and fig. 2 is a schematic structural view of a passive yarn take-up drum positioning mechanism of the present invention.

The utility model provides an efficient single yarn starching machine which characterized in that: the yarn guide device comprises a machine table 1, a passive yarn winding drum positioning mechanism 2, a first guide roller mechanism 3, a sizing chamber 4, a drying chamber 5, a second guide roller mechanism 6, a driving yarn winding drum positioning mechanism 7, a winding drum distance adjusting mechanism 8, a winding drum rotating mechanism 9, an immersion roller 10, a cam 11, a cam swinging mechanism 12, a cam lifting mechanism 13, a slurry brush 14, a slurry pool 15 and a heating rod 16, wherein the machine table 1 is sequentially provided with the passive yarn winding drum positioning mechanism 2, the first guide roller mechanism 3, the sizing chamber 4, the drying chamber 5, the second guide roller mechanism 6 and the driving yarn winding drum positioning mechanism 7, the machine table 1 is internally fixed with the winding drum distance adjusting mechanism 8 and the winding drum rotating mechanism 9, the passive yarn winding drum positioning mechanism 2 is connected on a horizontal linear guide rail of the machine table 1 in a sliding manner, the bottom of the passive yarn winding drum positioning mechanism 2 is fixed on a sliding seat of the winding drum distance adjusting mechanism 8, the driving yarn winding drum positioning mechanism 7 is fixed on an output shaft of the winding drum rotating mechanism 9, a cam lifting mechanism 13 is fixed on the sizing chamber 4, a piston rod of the cam lifting mechanism 13 is fixed on a cam swinging mechanism 12, a cam 11 is connected on the cam swinging mechanism 12, a connecting plate is fixedly connected on the cam 11, an immersion roller 10 is rotatably connected on the connecting plate, a sizing brush 14 is fixed at the bottom of the cam swinging mechanism 12, a sizing solution pool 15 is arranged in the sizing chamber 4, and a heating rod 16 is fixed in an interlayer of a bottom plate of the sizing solution pool 15. The heating rod 16 is capable of heating the slurry tank 15, and thus the slurry within the slurry tank 15.

As shown in fig. 2, the passive yarn winding drum positioning mechanism 2 comprises a base 21, an upper seat 22, a top plate 23, and a top plate lifting cylinder 24, wherein a first shaft rod is fixed on the bottom surface of the top plate 23, a second shaft rod is fixed on the upper plane of the upper seat 22, the first shaft rod and the second shaft rod are coaxial and have the same diameter, the upper seat 22 is rotatably connected to the base 21 through a shaft, the base 21 is connected to the machine table 1 in a sliding manner, and the base 21 is fixed on a sliding seat of the winding drum distance adjusting mechanism 8.

Firstly, the winding drum is placed on the upper layer seat 22, the second shaft rod on the upper layer seat 22 penetrates through the opening at the bottom of the winding drum, then the top plate lifting cylinder 24 drives the top plate 23 to move downwards, and the first shaft rod at the bottom of the top plate 23 is inserted into the upper opening of the winding drum, so that the winding drum can axially rotate along the first shaft rod and the second shaft rod.

Specifically, the first wire guiding roller mechanism 3 and the second wire guiding roller mechanism 6 are respectively composed of a lifting linear module 61, a width adjusting seat 62, an upper wire guiding roller 63 and a lower wire guiding roller 64, a cylinder body of the lifting linear module 61 is fixed on the machine table 1, the width adjusting seat 62 is fixed on a sliding seat of the lifting linear module 61, and the two sliding seats of the width adjusting seat 62 are respectively and rotatably connected with the upper wire guiding roller 63 and the lower wire guiding roller 64;

the width adjusting base 62 is composed of a base body, sliding seats, a positive and negative thread lead screw and a motor, wherein the motor is fixed on the base body, the positive and negative thread lead screw is rotatably connected on the base body, one end of the positive and negative thread lead screw is fixed on an output shaft of the motor, the positive thread section and the negative thread section of the positive and negative thread lead screw are respectively in threaded connection with ball nuts, the two ball nuts are respectively fixed on the two sliding seats, and the two sliding seats are both in sliding fit connection on the base.

The lifting linear module 61 can drive the width adjusting seat 62 and the upper guide roller 63 and the lower guide roller 64 on the width adjusting seat 62 to lift up and down, so as to control the upper and lower angles of the yarn, and enable the yarn to run more efficiently and stably.

The motor of the width adjusting seat 62 drives the positive and negative thread screw to rotate, so that two ball nuts and two sliding seats can be driven to move reversely or move relatively along the seat body, and the opening and closing of the upper guide roller 63 and the lower guide roller 64 are realized, so that the tightness of yarn clamped by the upper guide roller 63 and the lower guide roller 64 can be controlled according to requirements.

The driving yarn winding drum positioning mechanism 7 is a chuck which is fixed on an output shaft of a winding drum rotating mechanism 9, and the winding drum rotating mechanism 9 is a motor.

The winding drum is placed at the center of the chuck, the chuck orders about a plurality of fingers to be folded, the winding drum is held and fixed, and finally, the winding drum rotating mechanism 9 orders about the chuck to rotate, so that the winding drum can be driven to rotate axially.

The winding drum distance adjusting mechanism 8 is a horizontal linear module. The winding drum distance adjusting mechanism 8 can drive the driven yarn winding drum positioning mechanism 2 to drive the winding drums to horizontally and linearly move, so that the distance between the left winding drum and the right winding drum can be controlled, and the yarn transmission distance can be adjusted.

The cam swing mechanism 12 is composed of a box body 121, a rack 122, a single-rod cylinder 123, a shaft and a gear, the box body 121 is fixed on a piston rod of the cam lifting mechanism 13, the shaft is fixed on the cam 11, the cam 11 is rotatably connected to the box body 121 through the shaft, the gear is fixed on the shaft of the cam 11, the single-rod cylinder 123 is fixed in the box body 121, the rack 122 is fixed on the piston rod of the single-rod cylinder 123, and the rack 122 is meshed with the gear.

The piston rod of the single-rod cylinder 123 extends and retracts to drive the rack 122 to move horizontally and linearly, the rack 122 can drive the gear meshed with the rack to rotate back and forth, and the gear drives the cam 11 and the immersing roller 10 to swing back and forth. The oscillating submerged roller 10 agitates the slurry in the slurry tank 15 to provide a more uniform slurry.

The cam elevating mechanism 13 is a cylinder.

Two ends of the opening of the slurry pool 15 are respectively connected with a guide wheel 17 in a rotating way.

As shown in fig. 1, the yarn winding drum to be sized is positioned on the passive yarn winding drum positioning mechanism 2, and the empty winding drum is positioned on the active yarn winding drum positioning mechanism 7. One end of the yarn passes through the space between an upper yarn guide roller 63 and a lower yarn guide roller 64 on a first yarn guide roller mechanism 3, then passes through the sizing chamber 4, then passes through the drying chamber 5, then passes through the space between the upper yarn guide roller 63 and a lower yarn guide roller 64 on a second yarn guide roller mechanism 6, and finally is wound on a winding drum on a driving yarn winding drum positioning mechanism 7.

The active yarn winding drum positioning mechanism 7 drives the winding drum to rotate, so that the yarn can be dragged to be transmitted, and the cam lifting mechanism 13 drives the immersion roller 10 to move towards the yarn below until the yarn is pressed into the slurry tank 15 for sizing. And the sized yarn passes through the size pool 15 and then is rubbed by the size brush 14, so that the yarn sizing is more uniform. Then the yarn is dried by the drying chamber 5 and finally wound on a winding drum on the active yarn winding drum positioning mechanism 7.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims

1. The utility model provides an efficient single yarn starching machine which characterized in that: comprises a machine table (1), a passive yarn winding drum positioning mechanism (2), a guide roller mechanism I (3), a sizing chamber (4), a drying chamber (5), a guide roller mechanism II (6), an active yarn winding drum positioning mechanism (7), a winding drum distance adjusting mechanism (8), a winding drum rotating mechanism (9), an immersion roller (10), a cam (11), a cam swing mechanism (12), a cam lifting mechanism (13), a slurry brush (14), a slurry pool (15) and a heating rod (16), wherein the machine table (1) is sequentially provided with the passive yarn winding drum positioning mechanism (2), the guide roller mechanism I (3), the sizing chamber (4), the drying chamber (5), the guide roller mechanism II (6) and the active yarn winding drum positioning mechanism (7), the winding drum distance adjusting mechanism (8) and the winding drum rotating mechanism (9) are fixed in the machine table (1), and the passive yarn winding drum positioning mechanism (2) is connected to a horizontal linear guide rail of the machine table (1) in a sliding fit manner, the bottom of a passive yarn winding drum positioning mechanism (2) is fixed on a sliding seat of a winding drum distance adjusting mechanism (8), an active yarn winding drum positioning mechanism (7) is fixed on an output shaft of a winding drum rotating mechanism (9), a cam lifting mechanism (13) is fixed on a sizing chamber (4), a piston rod of the cam lifting mechanism (13) is fixed on a cam swinging mechanism (12), a cam (11) is connected on the cam swinging mechanism (12), a connecting plate is fixedly connected on the cam (11), an immersion roller (10) is rotatably connected on the connecting plate, a sizing brush (14) is fixed at the bottom of the cam swinging mechanism (12), a sizing pool (15) is arranged in the sizing chamber (4), and a heating rod (16) is fixed in an interlayer of a bottom plate of the sizing pool (15).

2. A high efficiency single yarn sizing machine according to claim 1, wherein: the passive yarn winding drum positioning mechanism (2) is composed of a base (21), an upper layer seat (22), a top plate (23) and a top plate lifting cylinder (24), a first shaft rod is fixed on the bottom surface of the top plate (23), a second shaft rod is fixed on the upper plane of the upper layer seat (22), the first shaft rod and the second shaft rod are coaxial and have the same diameter, the upper layer seat (22) is rotatably connected onto the base (21) through a shaft, the base (21) is connected onto a machine table (1) in a sliding fit mode, and the base (21) is fixed onto a sliding seat of a winding drum distance adjusting mechanism (8).

3. A high efficiency single yarn sizing machine according to claim 1, wherein: the wire guide roller mechanism I (3) and the wire guide roller mechanism II (6) are composed of a lifting linear module (61), a width adjusting seat (62), an upper wire guide roller (63) and a lower wire guide roller (64), a cylinder body of the lifting linear module (61) is fixed on the machine table (1), the width adjusting seat (62) is fixed on a sliding seat of the lifting linear module (61), and the upper wire guide roller (63) and the lower wire guide roller (64) are respectively and rotatably connected onto two sliding seats of the width adjusting seat (62);

the width adjusting seat (62) is composed of a seat body, sliding seats, a positive and negative thread screw rod and a motor, the motor is fixed on the seat body, the positive and negative thread screw rod is rotatably connected to the seat body, one end of the positive and negative thread screw rod is fixed on an output shaft of the motor, ball nuts are respectively in threaded connection on a positive thread section and a negative thread section of the positive and negative thread screw rod, the two ball nuts are respectively fixed on the two sliding seats, and the two sliding seats are all in sliding fit connection on the seat body.

4. A high efficiency single yarn sizing machine according to claim 1, wherein: the driving yarn winding drum positioning mechanism (7) is a chuck which is fixed on an output shaft of the winding drum rotating mechanism (9), and the winding drum rotating mechanism (9) is a motor.

5. A high efficiency single yarn sizing machine according to claim 1, wherein: the take-up drum distance adjusting mechanism (8) is a horizontal linear module.

6. A high efficiency single yarn sizing machine according to claim 1, wherein: the cam swing mechanism (12) is composed of a box body (121), a rack (122), a single-rod cylinder (123), a shaft and a gear, the box body (121) is fixed on a piston rod of the cam lifting mechanism (13), the shaft is fixed on the cam (11), the cam (11) is rotatably connected to the box body (121) through the shaft, the gear is fixed on the shaft of the cam (11), the single-rod cylinder (123) is fixed in the box body (121), the rack (122) is fixed on the piston rod of the single-rod cylinder (123), and the rack (122) is meshed with the gear.

7. A high efficiency single yarn sizing machine according to claim 1, wherein: the cam lifting mechanism (13) is an air cylinder.

8. A high efficiency single yarn sizing machine according to claim 1, wherein: two ends of the opening of the slurry pool (15) are respectively and rotatably connected with a guide wheel (17).