DE102013223664B4 - twine take-up device - Google Patents

Abstract

A yarn take-up device (100) having a plurality of rollers (21, 22) rotated to move a yarn (Y), comprising: a heat-insulating box (23) in which the rollers (21, 22) are housed; and an air duct (24) arranged on the heat-insulating box (23), characterized in that the air duct (24) is adapted to deliver high-temperature air in the heat-insulating box (23) to a low-air-temperature area in the heat-insulating box ( 23) and that a duct inlet (24i) and a duct outlet (24o) of the air duct (24) are provided in a door portion of the heat insulating box (23).

Description

technical field

The present invention relates to one type of yarn take-up device. More specifically, the present invention relates to a type of yarn take-up device that reduces operating costs.

Technical background

Conventionally, there is known a yarn take-up device that has a plurality of rollers that are rotated to pay out a yarn (see, for example, JP 2011-122276 A ). Such a yarn take-up device has preheating rolls that heat the yarn to a drawing temperature and heat setting rolls that heat the yarn to a heat setting temperature.

A yarn take-up device is known in which preheating rollers and heat-setting rollers are housed in a heat-insulating box (see, for example, JP 2012-36526 A ). By accommodating the preheating rollers and the heat setting rollers in the heat-insulating box, power consumption of the electric heaters provided inside each roller is suppressed to enable reduction in running costs. However, there is a problem when a low air temperature area exists in the heat-insulating box that the power consumption of the rollers arranged in the low air temperature area cannot be suppressed and the running cost cannot be sufficiently reduced.

The EP 2 505 699 A1 relates to the preamble of claims 1, 3 and 4, and from U.S. 3,552,923 A a similar device emerges.

Presentation of the invention

Problem solved by the invention

The purpose of the present invention is to provide a yarn take-up device that directs high-temperature air in a heat-insulating box to a low-air temperature area to reduce power consumption of the rollers located in the low-air temperature area, thereby reducing running costs .

ways to solve the task

This object is solved by the subject matter of claims 1, 3 and 4. Preferred embodiments can be found in the further claims.

effect of the invention

The present invention achieves the following effects. According to the invention, the yarn take-up device includes the heat-insulating box in which the rollers are housed and the air duct attached to the heat-insulating box. The air duct guides high-temperature air in the heat-insulating box to the low-air-temperature area in the heat-insulating box. Consequently, in the yarn take-up device, the rollers located in the low air temperature area are heated to suppress the power consumption of the rollers. Therefore, the yarn take-up device reduces running costs.

According to some embodiments, the air duct introduces a high temperature air flow generated by rotation of the rollers and directs the high temperature air. Consequently, the yarn take-up device does not need a fan or the like, and the construction of the yarn take-up device is simplified.

According to an embodiment, the duct inlet and the duct outlet of the air duct are provided in the door portion of the heat insulating box. Consequently, the air duct is opened and closed together with the door portion, so that the serviceability of the yarn take-up device is improved.

According to one embodiment, the duct inlet of the air duct is formed at a position substantially symmetrical with respect to the plane of symmetry between two of the rollers rotated opposite to each other. Consequently, in the yarn take-up device, the air duct guides the high-temperature airflow without any disturbance, thereby efficiently guiding the high-temperature airflow.

According to an embodiment, the duct outlet of the air duct is provided at the position opposite to the end surfaces of the rollers. Consequently, the high-temperature airflow passed through the air duct hits the end surfaces of the rollers and is diffused in the yarn take-up device, thereby preventing the vibration of the yarn generated by the high-temperature airflow.

According to a preferred embodiment, the air duct has the flow rate control means that controls a flow rate of the high-temperature air. Consequently, the yarn take-up device controls the flow rate of the air at high

Temperature appropriately and then directs the air to the low air temperature area.

character list

• 1 Fig. 12 is a drawing of the entire construction of a yarn take-up device 100.
• 2 Fig. 12 is a drawing of a holding roller assembly 20.
• 3 Fig. 12 is a drawing of high-temperature airflow generated by rotation of heat-setting rollers 22a and 22b.
• 4 FIG. 14 is a drawing in which an air duct 24 guides high-temperature air.
• 5 Fig. 13 is a drawing of a rotation of a door portion 23d of a heat insulating box 23.
• 6 Fig. 12 is a drawing of a duct inlet 24i of the air duct 24.
• 7 Fig. 12 is a drawing of a duct outlet 24o of the air duct 24.
• 8th 12 is a drawing of a nip roller assembly 20 according to another embodiment.
• 9 Fig. 12 is a drawing of an air line 24 with a flow rate control means 27.

Detailed description of the invention

First, an explanation will be given of a yarn take-up device 100 according to an embodiment of the present invention.

1 12 is a drawing of an overall construction of the yarn take-up device 100. Generally, a yarn take-up device is divided into a device that produces a fully drawn yarn (FDY) made by fully drawing a yarn and a device that produces a partially oriented yarn (POY), made by partially stretching a yarn. Yarn take-up device 100 produces the fully drawn yarn (FDY).

The yarn take-up device 100 spins a filament F, applies a desired characteristic to a yarn Y made by bundling the filament F, and then winds the yarn Y to produce a package P. The yarn take-up device 100 mainly comprises a spinning device 10, a holding roller group 20 and a winding device.

The spinning device 10 spins a plurality of filaments F. Synthetic fiber material (material of the filaments F) is discharged under pressure through an extruder and spun through a plurality of spinning orifices provided in a spinning head. The filaments F spun by the spinning device 10 are passed under the spinning device 10 .

The filaments F spun by the spinning device 10 are bundled for every predetermined number to form a plurality of yarns Y . Then, the yarns Y produced by bundling the filaments F are guided to the nip roller group 20 via an oiling device.

The nip roller group 20 draws the yarn Y and heat-sets the drawn yarn Y . Here, “stretching” denotes a process in which the yarn Y is elongated under a predetermined thermal condition to improve the molecular orientation of the yarn Y, thereby forming whiskers. "Heat setting" means a process in which the yarn Y is kept under a predetermined thermal condition to facilitate molecular alignment of an amorphous region. As a result, desired characteristics are obtained and the characteristics are stabilized.

The holding roller group 20 is divided into a preheating roller group 20H and a heat setting roller group 20T (see 2 ). The yarn Y fed to the holding roller group 20 is heated to a drawing temperature by preheating rollers 21 constituting the preheating roller group 20H. Then, the yarn Y heated by the preheating rollers 21 is appropriately stretched and then heated to the heat setting temperature by the heat setting rollers 22 constituting the heat setting roller group 20T. Then, the yarn Y after heat setting is delivered to the winding device 30 .

The winding device 30 winds the yarn Y paid out from the holding roller group 20 to form the package P. As shown in FIG. A plurality of bobbins B are attached to a bobbin holder 31 of the winding device 30 . By rotating the bobbin holder 31, the bobbins B are rotated integrally with the bobbin holder 31. FIG. Consequently, the winding device 30 winds the plurality of yarns Y simultaneously to form the packages P on each of the bobbins B .

Next, a detailed explanation of the holding roller group 20 will be given.

2 Fig. 14 is a drawing of the nip roller group 20. Arrows in the drawing indicate the feeding directions of the yarn Y.

As mentioned above, the holding roller group 20 is divided into the preheating roller group 20H and 20H the heat setting roller group 20T. In the yarn take-up device 100, the preheating roller group 20H has preheating rollers 21. FIG. An electric heater 21h, which is temperature control means, is provided in each of the preheating rollers 21 to adjust the surface temperature of each preheating roller 21 appropriately. On the other hand, the heat setting roller group 20T includes two heat setting rollers 22. An electric heater 22h, which is temperature control means, is provided in each of the heat setting rollers 22 so that the surface temperature of each heat setting roller 22 is appropriately adjusted.

Herein, the preheating rollers 21 constituting the preheating roller group 20H are defined as a preheating roller 21a, a preheating roller 21b, and a preheating roller 21c from the upstream side in the feeding directions of the yarn Y. The heat setting rollers 22 constituting the heat setting roller group 20T are defined as a heat setting roller 22a and a heat setting roller 22b from the upstream side in the yarn Y feeding directions.

The yarn Y passed through the preheating roller group 20H is heated to a temperature suitable for drawing by the preheating roller group 20H. That is, the yarn Y passed through the preheating roller group 20H is wound on the preheating rollers 21a, 21b and 21c set at a predetermined surface temperature to be heated to the drawing temperature. Then, the yarn Y heated to the drawing temperature is paid out from the preheating roller group 20H and guided to the heat setting roller group 20T. At this time, the peripheral speed of the heat setting roller 22a, which is arranged on the most upstream side in the feeding directions of the yarn Y, is higher than the peripheral speed of the preheating roller 21c, which is arranged on the most downstream side, whereby the yarn Y is stretched between the preheating roller 21c and the heat setting roller 22a.

The yarn Y fed to the heat setting roller group 20T is heated to a temperature suitable for heat setting by the heat setting roller group 20T. More specifically, the yarn Y guided to the heat-setting roller group 20T is wound on the heat-setting rollers 22a and 22b set at predetermined surface temperatures to be heated to the heat-setting temperature. Then, the yarn Y after heat setting is paid out from the heat setting roller group 20T and guided to the winding device 30. FIG.

In the yarn take-up device 100, the support roller group 20 is accommodated in a heat-insulating box 23. As shown in FIG. Concretely, the preheating rollers 21a, 21b and 21c and the heat setting rollers 22a and 22b constituting the holding roller group 20 are housed in the one heat insulating box 23. As shown in FIG. The preheating rollers 21a, 21b and 21c are arranged in a lower portion of the interior of the heat insulating box 23, and the heat setting rollers 22a and 22b are arranged in an upper portion of the interior of the heat insulating box 23.

Air heated by the preheating rollers 21a, 21b and 21c and the heat setting rollers 22a and 22b flows upward against the direction of gravity. That is, as the heated air expands and its density decreases, the air is pushed upwards by surrounding air (called natural convection). Then, the heat setting rollers 22a and 22b are heated by the high-temperature air collected in the upper portion of the interior of the heat-insulating box 23, thereby reducing power consumption of the electric heater 22h. The preheating rollers 21a, 21b and 21c are heated by radiant heat from the heat setting rollers 22a and 22b and the like, thereby reducing power consumption of the electric heater 21h. Consequently, energy consumption is reduced by accommodating the preheating rollers 21a, 21b and 21c and the heat setting rollers 22a and 22b in the one heat insulating box 23, so that running costs are effectively reduced.

In the conventional yarn take-up device, low-temperature air accumulates in the lower part of the interior of the heat-insulating box 23, whereby a low-air-temperature area may form in the lower portion. In the heat insulating box 23, an inlet port 23i and an outlet port 23o for the yarn Y are provided, allowing a low air temperature region to be formed in the vicinity thereof. Then, there arises a problem that power consumption of the roller arranged in the low air temperature area (in this embodiment, the preheating roller 21a) cannot be reduced, whereby the running cost cannot be sufficiently reduced. At this point, in the yarn take-up device 100, there is provided an air duct 24 that guides high-temperature air in the heat-insulating box 23 to the low-air temperature area (the periphery of the preheating roller 21a in this embodiment), thereby solving the problem.

Now, the structure that solves the above problem will be explained.

3 Fig. 12 is a drawing of the high temperature air flow generated by the rotation of the heat setting rollers 22a and 22b. 4 FIG. 14 is a drawing in which the air duct 24 guides the high-temperature air. arrows in 4 show the direction of high temperature air flow. Hereinafter, the direction of gravity is defined as the vertical direction, and directions of rotation axes La and Lb of the heat setting rollers 22a and 22b are defined as the lateral direction.

As mentioned above, the air heated by the preheating rollers 21a, 21b and 21c and the heat setting rollers 22a and 22b flows upward against the direction of gravity. As a result, in the upper portion of the interior of the heat insulating box 23, the high-temperature air accumulates and a high-air-temperature area is formed.

In this embodiment, the heat setting rollers 22 a and 22 b are arranged in the upper portion of the interior of the heat insulating box 23 . Namely, the heat setting rollers 22a and 22b are disposed in the high air temperature area. Since the heat setting rollers 22a and 22b are always heated by the electric heaters 22h, an air layer having an even higher temperature is formed around the heat setting rollers 22a and 22b. Also, since the heat setting roller 22a is rotated centering on the rotation axis La, the high-temperature air around the heat setting roller 22a is rotated centering on the rotation axis La (counterclockwise in the drawing). On the other hand, since the heat setting roller 22b is rotated centering on the rotation axis Lb, the high-temperature air around the heat setting roller 22b is also rotated centering on the rotation axis Lb (clockwise in the drawing). Hereinafter, the high-temperature air flow generated by the rotation of the heat setting roller 22a is referred to as an air flow Fa, and the high-temperature air flow generated by the rotation of the heat setting roller 22b is referred to as an air flow Fb.

In this embodiment, the heat setting rollers 22a and 22b are rotated counter to each other. Consequently, the air flow Fa and the air flow Fb are opposed to each other above the heat setting rollers 22a and 22b. Then, the airflow Fa and the airflow Fb collide with each other in a space constructed by the heat setting rollers 22a and 22b and the space above, thereby generating a lateral airflow Fc. The air flow Fc flows between the heat setting rollers 22a and 22b along the heat setting rollers 22a and 22b.

The air duct 24 introduces the air flow Fc, which is a high temperature air flow, and guides the high temperature air to the low air temperature area. The air duct 24 is provided so that a duct inlet 24i thereof faces the space constructed by the heat setting rollers 22a and 22b. Consequently, the air flow Fc is introduced into the air duct 24 . A duct outlet 24o of the air duct 24 is provided near the preheating roller 21a. This is because the periphery of the preheating roller 21a is the low air temperature area in this embodiment.

According to this construction, the preheating roller 21a, which is disposed in the low air temperature region in the yarn take-up device 100, is heated, so that the power consumption of the preheating roller 21a is reduced. Therefore, the yarn take-up device 100 reduces running costs.

Furthermore, into the air duct 24, the high-temperature air flow generated by the rotations of the heat setting rollers 22a and 22b (the air flow Fc) is introduced, and the high-temperature air is ducted. Consequently, the yarn take-up device 100 does not require a fan or the like, and the construction of the yarn take-up device 100 is simplified.

Next, an explanation will be given of the reason why the duct inlet 24i and the duct outlet 24o of the air duct 24 are provided in a door portion 23d of the heat insulating box 23. FIG.

5 Fig. 13 is a drawing of rotation of the door portion 23d of the heat insulating box 23. Arrows in 5 show the direction of rotation of the door portion 23d.

In this embodiment, the duct inlet 24 i and the duct outlet 24 o of the air duct 24 are provided in the door portion 23 d of the heat insulating box 23 . The door portion 23d is arranged perpendicularly to the lateral direction and covers the end surfaces of the preheating rollers 21a, 21b and 21c and the heat setting rollers 22a and 22b (see Fig 4 ). In this embodiment, the door portion 23d is rotatably mounted centering on a rotation axis Lr. Consequently, the air duct 24 is opened and closed together with the door portion 23d, so that the serviceability of the yarn take-up device 100 is improved. Next, an explanation will be given of the detailed shape of the duct inlet 24i and a detailed position of the duct outlet 24o.

6 Figure 12 is a drawing of the duct inlet 24i of the air duct 24. 7 is a drawing of Line outlet 24o of the air line 24. Arrows both in 6 as well as in 7 show the directions of high temperature airflow.

In this embodiment, the duct inlet 24i of the air duct 24 is formed at a position that is substantially symmetrical with respect to a plane of symmetry between the heat setting rollers 22a and 22b rotated opposite to each other. Concretely, the duct inlet 24i of the air duct 24 is formed substantially like a fan from a termination point X of the heat setting rollers 22a and 22b along the outer circumference of the heat setting rollers 22a and 22b. As mentioned above, the air flow Fc flows between the heat setting rollers 22a and 22b along the heat setting rollers 22a and 22b. Consequently, in the yarn take-up device 100, the high-temperature airflow (the airflow Fc) is introduced into the air duct 24 without any disturbance, thereby efficiently guiding the high-temperature airflow.

Moreover, the duct outlet 24o of the air duct 24 is provided at a position opposite to the end surface of the preheating roller 21a so as to apply the high-temperature air flow guided through the air duct 24 to the end surface of the preheating roller 21a. Consequently, in the yarn take-up device 100, the high-temperature airflow passed through the air duct 24 hits the end surface of the preheating roller 21a and is diffused, thereby preventing the vibration of the yarn Y generated by the high-temperature airflow.

Next, the case where the yarn take-up device 100 has a holding roller group 20 according to another embodiment will be explained.

8th 12 is a drawing of the nip roller assembly 20 according to another embodiment. arrows in 8th show the feed directions of yarn Y.

In this embodiment, the preheating rollers 21a, 21b and 21c and the heat setting rollers 22a and 22b constituting the holding roller group 20 are accommodated in the one heat insulating box 23 as well. But in the nip roller group 20 according to this embodiment, a protective cover 25 covering the preheating roller 21c is provided so that the surface temperature of the preheating roller 21c, which discharges the yarn Y to a stretching section (between the preheating roller 21c and the heat setting roller 22a), by the Preheating rollers 21a and 21b and the heat setting rollers 22a and 22b is not affected and changed. Since the low air temperature area is formed near the exit port 23o, a protective wall 26 is provided above the heat setting roller 22a. In addition, a protective wall 26 is suitably provided between the preheating rollers 21a, 21b and 21c and the heat setting rollers 22a and 22b.

In this embodiment, the high-temperature air flow generated by the protective cover 25 and the protective wall 26 is introduced into the air duct 24 . Consequently, in the yarn take-up device 100, the high-temperature airflow is introduced into the air duct 24 without disturbance, thereby efficiently guiding the high-temperature airflow.

Next, an explanation will be given about a configuration applied to the yarn take-up device 100. FIG.

9 Fig. 12 is a drawing of the air duct 24 with a flow rate control means 27. Arrows in the figure show the direction of high temperature air flow.

In this embodiment, the air duct 24 has the flow rate control means 27 which controls a flow rate of the high-temperature air. Concretely, as the flow rate control means 27, a throttle valve is provided so that a passage area of the air duct 24 is changed, thereby controlling an appropriate flow rate of the high-temperature air. Consequently, the yarn take-up device 100 suitably controls the flow rate of the high-temperature air, and then directs the air to the low-air-temperature area.

Reference List

10

spinning device

20a

holding roller group

20H

preheat roller group

20T

heat curing roller group

21

preheat roller

21a

preheat roller

21b

preheat roller

21c

preheat roller

21h

electric heating

22

heat curing roller

22a

heat curing roller

22b

heat curing roller

10 p.m

electric heating

23

heat-insulating box

23i

intake port

23o

exhaust port

24

air line

24i

line inlet

24o

line outlet

30

winding device

100

twine take-up device

fa

airflow

color

airflow

FC

airflow

Y

yarn

Claims (6)

A yarn take-up device (100) having a plurality of rollers (21, 22) rotated to move a yarn (Y), comprising: a heat-insulating box (23) in which the rollers (21, 22) are housed; and an air duct (24) arranged on the heat-insulating box (23), characterized in that the air duct (24) is adapted to deliver high-temperature air in the heat-insulating box (23) to a low-air-temperature area in the heat-insulating box (23). Box (23) to conduct, and that a duct inlet (24i) and a duct outlet (24o) of the air duct (24) are provided in a door portion of the heat insulating box (23). Yarn take-up device (100) after claim 1 characterized in that the air duct (24) is designed to introduce a high temperature air flow generated by rotation of the rollers (21, 22) and the air duct (24) guides the high temperature air. A yarn take-up device (100) having a plurality of rollers (21, 22) rotated to move a yarn (Y), comprising: a heat-insulating box (23) in which the rollers (21, 22) are housed; and an air duct (24) arranged on the heat-insulating box (23), characterized in that the air duct (24) is adapted to deliver high-temperature air in the heat-insulating box (23) to a low-air-temperature area in the heat-insulating box (23). Box (23) that the air duct (24) is designed to introduce a high temperature air flow generated by rotation of the rollers (21, 22) and the air duct (24) guides the high temperature air and that the duct inlet (24i) of the air duct (24) is arranged at a position substantially symmetrical with respect to a plane of symmetry between two of the rollers (21, 22) rotated counter to each other. A yarn take-up device (100) having a plurality of rollers (21, 22) rotated to move a yarn (Y), comprising: a heat-insulating box (23) in which the rollers (21, 22) are housed; and an air duct (24) arranged on the heat-insulating box (23), characterized in that the air duct (24) is adapted to deliver high-temperature air in the heat-insulating box (23) to a low-air-temperature area in the heat-insulating box (23). Box (23) that the air duct (24) is designed to introduce a high temperature air flow generated by rotation of the rollers (21, 22) and the air duct (24) guides the high temperature air , and that the duct outlet (24o) of the air duct (24) is provided at a position opposite to end surfaces of the rollers (21, 22). Yarn take-up device (100) after claim 3 or 4 , characterized in that a duct inlet (24i) and a duct outlet (24o) of the air duct (24) are provided in a door portion of the heat insulating box (23). Yarn take-up device (100) according to one of Claims 1 until 5 , characterized in that the air duct (24) has a flow rate control means that controls a flow rate of air.

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