JP2004100094A - Fiber bundle-collecting device in spinning machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fiber bundle-collecting device capable of improving yarn quality by reducing the occurrence of fluff compared to that by a conventional fiber bundle-collecting device by a simple structure. <P>SOLUTION: This fiber bundle-collecting device 30 is installed on the downstream side of a final delivery roller pair of a draft device, and has a delivery part 31, and a sucking pipe 32 installed so as to extend to the upstream side in the traveling direction of the fiber bundle F from the nipping point of the delivery part 31, and having a sliding face with a sucking hole 32a. A wound member 33 is installed at the opposite side to the sucking pipe 32 so as to place the bottom nip roller 35a constituting the delivery part 31 between them. An air-permeable apron 34 is wound over the sucking pipe 32, the wound member 33 and the bottom nip roller 35a. The wound member 33 is installed as a separated body from the sucking pipe 32 to increase a fleece angle. The sucking pipe 32 is connected to a duct through a connecting pipe 48, and the duct is connected to a sucking device. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a fiber bundle concentrating device for a spinning machine, and more particularly, to a fiber bundle concentrating device for a spinning machine which is disposed downstream of a draft device (draft part) of a spinning machine and collects fiber bundles drafted by the draft device. It is.
[0002]
[Prior art]
Conventionally, as a fiber bundle concentrating device of this type, a delivery roller pair 63 having a porous apron 62 is provided downstream of a final roller pair 61 of a draft device as shown in FIG. A device provided with an air suction device 64 for applying an airflow is disclosed (for example, see Patent Document 1). In this fiber bundle concentrator, suction airflow acts on the transport surface of the porous apron 62 via a suction slot formed in the apron cage 65 for guiding the porous apron 62.
[0003]
As shown in FIG. 8, a delivery roller pair 73 having a porous apron 72 forming a fiber bundle transport surface is provided downstream of the final roller pair 71 constituting the draft device, and a transport surface of the porous apron 72 is provided on the transport surface of the porous apron 72. A device provided with an air suction device 74 for applying a suction airflow is disclosed (for example, see Patent Document 2). In this device, a suction airflow acts on the transport surface of the porous apron 72 via a slot formed in an apron guide 75 for guiding the porous apron 72. Further, the porous apron 72 is configured to be rotated while being tensioned by the guide member 76.
[0004]
Further, a hollow profile (guide cylinder) which forms a stationary sliding surface having a suction slit is provided on the bottom side downstream of the final roller of the drafting device, and a fiber having a configuration in which a perforated belt for transportation is wound around the hollow profile. A bundle focusing device is also disclosed (for example, see Patent Document 3). In this apparatus, a nip roller is provided on the top side to abut the perforated belt to define a nip point. The nip roller is driven by the last roller via a transfer belt. A configuration in which the nip roller is driven via a transfer roller that contacts the final roller instead of driving the nip roller via a transfer belt is also disclosed.
[0005]
[Patent Document 1]
JP-A-7-238425 (paragraph numbers [0012] to [0015], FIGS. 1 to 3)
[Patent Document 2]
DE-A-197 08 410 A1 (FIG. 1)
[Patent Document 3]
JP-A-11-286837 (paragraph numbers [0017] to [0024], FIGS. 1 and 1)
[0006]
[Problems to be solved by the invention]
In the case where the yarn is spun with a spinning machine equipped with the above-described fiber bundle concentrating device, the occurrence of fluff is reduced and the yarn spots are also reduced as compared with the case where the yarn is spun with a spinning machine not equipped with the fiber bundle concentrating device. Although it decreases and U% improves, further improvement is desired.
[0007]
Conventionally, it is known that increasing the fleece angle (fleece angle) has the effect of suppressing the generation of fluff. However, increasing the fleece angle has a disadvantage that thread breakage is likely to occur, and the fleece angle is increased. That was a big negative in operation. Here, the "fleece angle" means a line connecting the center of curvature of the arc surface guiding the fiber bundle to the drawing position after the fiber bundle (fleece) passes through the nip point and the nip point, and the center of curvature and the fiber. It means an angle formed by a line segment connecting the drawing point of the bundle F.
[0008]
In the conventional fiber bundle concentrator, no special consideration has been given to improving the yarn quality by increasing the fleece angle to suppress the generation of fluff. For example, in Patent Literature 1, as shown in FIG. 7, the fiber bundle F is drawn almost tangentially downstream of the nip point of the delivery roller pair 63, and no consideration is given to increasing the fleece angle. Also, in Patent Document 2, the fiber bundle F is drawn almost tangentially on the downstream side of the nip point of the delivery roller pair 73, and no consideration is given to increasing the fleece angle.
[0009]
The applicant of the present application has actively manufactured a fiber bundle concentrating device having a large fleece angle, equipped the spinning machine, and photographed the state of the yarn at the time of spinning with a high-speed video camera. The state of the yarn at the time of spinning of the spinning machine equipped with the device was compared. As a result, when the fleece angle is increased, the yarn (fiber bundle) reciprocates while rolling along the apron on the downstream side of the nip point of the delivery roller pair, whereas the fleece angle is small. In the case of, it was observed that the yarn reciprocated so as to slip. Also, as a result of measuring the Haininess and U% of the spun yarn, the U% was almost the same, but the Haininess was clearly superior when the fleece angle was actively increased. The present inventors have completed the present invention based on this finding.
[0010]
SUMMARY OF THE INVENTION An object of the present invention is to provide a fiber bundle convergence device for a spinning machine that can improve the yarn quality by suppressing the generation of fluff with a simple configuration compared to a conventional fiber bundle convergence device.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 is a fiber bundle concentrating device that bundles fiber bundles drafted in a draft part of a spinning machine. A delivery section provided downstream of the final delivery roller pair of the draft part and having a nip roller; and a suction section provided to extend upstream of the nip point of the delivery section in the moving direction of the fiber bundle. A suction unit having a sliding surface provided with a hole, and a ventilation apron which constitutes the delivery unit and is rotated in contact with the sliding surface are provided. A wrapping member around which the ventilation apron is wrapped is provided separately from the suction unit on the downstream side in the moving direction of the fiber bundle from the suction unit to increase the fleece angle.
[0012]
In the present invention, the fiber bundle drafted in the draft part is bundled by the fiber bundle bundling device provided downstream of the final delivery roller pair of the draft part, and moves in a bundled state. As compared with a spinning machine not provided, generation of fluff and cotton loss are suppressed, and yarn quality is improved. In addition, since the fleece angle is increased by the wrapping member provided separately from the suction unit on the downstream side of the suction unit, the action of suppressing the generation of fluff is enhanced, and the generation of fluff is further suppressed, and the yarn quality is reduced. improves. After passing the nip point, the fiber bundle moves downstream while being twisted. Since the fiber bundle is pulled out from the nip point in a state of being bundled by the suction action of the suction hole, the twisting by the winding action can easily reach near the nip point, the yarn strength increases, and even if the fleece angle is increased, the yarn is increased. An increase in the number of cuts is suppressed.
[0013]
In the invention according to claim 2, in the invention according to claim 1, the winding member has a distance of 5 mm from the nip point to a position where the fiber bundle is separated from the ventilation apron on the downstream side of the nip point. It is provided so as to be as described above. In the present invention, since the distance until the fiber bundle that moves past the nip point separates from the ventilation apron is 5 mm or more, while the fiber bundle moves while rolling on the ventilation apron, the fiber floating from the fiber bundle is It becomes easy to be twisted into the fiber bundle, and the action of suppressing generation of fluff is improved.
[0014]
According to a third aspect of the present invention, in the second aspect of the invention, the suction portion around which the ventilation apron is wound and the winding member are detachably supported by a support portion provided on a machine frame. At least one end thereof is fitted to the supported portion to be supported. In the present invention, since the suction portion and the wrapping member are supported in a state where at least one end is fitted to the supported portion, it is easy to arrange both so that the distance becomes 5 mm or more.
[0015]
The invention according to claim 4 is the invention according to any one of claims 1 to 3, wherein the winding member is formed of a bar-shaped solid body. According to the present invention, the production is simplified as compared with the case where the wrapping member is formed in a tubular shape, and the wrapping member is less likely to be damaged even if the wrapping member collides with another member at the time of assembling, disassembling and maintenance work, or the like.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described below with reference to FIGS. FIG. 1 is a partially cut-away schematic side view showing one side of a draft device and a fiber bundle concentrating device, and FIG. 2A shows a fiber bundle drawing direction at a nip point (a moving direction of the fiber bundle in the draft device). FIG. FIG. 3 is a partially enlarged view of FIG.
[0017]
As shown in FIG. 1, the draft device 11 as a draft part has a three-wire configuration including a front bottom roller 12, a middle bottom roller 13, and a back bottom roller 14. The front bottom roller 12 is supported at a predetermined position with respect to a roller stand 15 constituting a machine frame, and the middle and back bottom rollers 13 and 14 are fixed to the roller stand 15 so as to be adjustable in the front-rear direction. It is supported via support brackets 13a and 14a. The support brackets 13a and 14a are fastened and fixed at predetermined positions by bolts and nuts (both not shown) penetrating through long holes formed in the roller stand 15. The bottom apron 16 is wound around the bottom tensor 17 and the middle bottom roller 13.
[0018]
On the weighting arm 18, a front top roller 19, a middle top roller 20, and a back top roller 21 are supported via top roller support members at positions corresponding to the front bottom roller 12, the middle bottom roller 13, and the back bottom roller 14, respectively. Have been. Each of the top rollers 19 to 21 is supported as a pair of two weights. The front bottom roller 12 and the front top roller 19 constitute a final delivery roller pair of the draft device 11.
[0019]
A lever 18a is provided on the weighting arm 18 so as to be rotatable between a pressing position and a releasing position. When the lever 18a is located at the pressing position where the lever 18a comes into contact with the frame 18b of the weighting arm 18 shown in FIG. 1, each of the top rollers 19 to 21 supported by the weighting arm 18 is moved to the bottom rollers 12, 13, 14 side. Is held in a locked state at a pressing position (spinning position) for pressing the substrate. When the lever 18a is turned from the state shown in FIG. 1 to the upper release position, the locked state is released.
[0020]
As shown in FIG. 1, a fiber bundle concentrating device 30 is disposed downstream of the final delivery roller pair of the draft device 11. The fiber bundle concentrating device 30 includes a delivery unit 31, a suction pipe 32 as a suction unit, a wrapping member 33, and a ventilation apron. The delivery unit 31 includes a bottom nip roller 35 a as a nip roller formed on a rotation shaft 35 disposed in parallel with the front bottom roller 12, and a top nip roller 31 a as a nip roller pressed on the bottom nip roller 35 a via a ventilation apron 34. It is composed of
[0021]
As shown in FIG. 2A, the fiber bundle concentrating device 30 of this embodiment includes a support member 36 (see FIG. 1) in which a top nip roller 31a is provided every two spindles in the same manner as the top rollers 19 to 21 of the draft device 11. 3 and shown in FIG. 3). In this embodiment, the support member 36 is formed integrally with the support member of the front top roller 19.
[0022]
On the other hand, the bottom side of the fiber bundle concentrating device 30 is configured such that half of the weight disposed between the roller stands 15 of the draft device 11, in this embodiment, four weights constitute one unit. At a middle position of the roller stand 15 arranged at a predetermined interval in the machine base longitudinal direction, a support arm constituting a machine frame with the base end side supported by a support beam 37 extending in the machine longitudinal direction. A rotation shaft 35 is supported between the roller stand 15 and the support arm 38 (see FIG. 2A only).
[0023]
As shown in FIG. 2B, the rotating shaft 35 is formed to have a predetermined length corresponding to a plurality of weights (four weights in this embodiment), and bearings 39 are fixed to both ends thereof. The bearing 39 is fitted to an end plug 40 as a supported portion, and as shown in FIG. 2A, the end plug 40 is provided on the roller stand 15 and the support arm 38 at the fitting portion 40a. The rotation shaft 35 is rotatably supported between the roller stand 15 and the support arm 38 by being supported by 38a. The support portions 15a and 38a are formed so as to be able to support two end plugs 40, and can support the end plugs 40 attached to the ends of the adjacent rotary shafts 35.
[0024]
The support portion 15a is formed of a block fixed on the roller stand 15, and has a fitting recess extending obliquely upward on the front side of the machine base. The support portion 38a also has a fitting recess extending obliquely upward on the front side of the machine. The end plug 40 has a fitting portion 40a that can be fitted into both fitting recesses, and is formed so that the fitting portion 40a can be fitted to the support portions 15a and 38a with one touch.
[0025]
The rotation shaft 35 is provided with a gear 41 at the center in the longitudinal direction so as to be able to rotate integrally with the rotation shaft 35. As shown in FIG. 3, a gear portion 12 a is formed on the front bottom roller 12 at a position facing the gear 41. Similarly to the support arm 38, an intermediate gear 43 is rotatably supported by a support arm 42 having a base end fixed to the support beam 37 in a state in which the intermediate gear 43 meshes with the gear portion 12a and the gear 41. That is, the rotational force of the front bottom roller 12 is transmitted to the rotating shaft 35 via the gear portion 12a, the intermediate gear 43, and the gear 41.
[0026]
As shown in FIG. 1, a duct 44 as a suction source (negative pressure source) for the fiber bundle concentrating device 30 is disposed in the spinning frame so as to extend in the longitudinal direction (perpendicular to the plane of FIG. 1). Is established. A plurality of ducts 44 are provided along the longitudinal direction of the spinning frame. A suction device 45 for making the inside of the duct 44 a negative pressure is connected to each duct 44 via a pipe 46. As the suction device 45, a fan motor that drives a fan 47a by a motor 47 is used. As shown in FIG. 1, the duct 44 is disposed in the center of the spinning frame above the rear side of the draft device 11, and the suction device 45 is disposed below the duct 44. The suction pipe 32 is connected to the duct 44 via a connecting pipe 48 in a state extending in parallel with the duct 44.
[0027]
The suction pipe 32 and the wrapping member 33 are also supported with both ends fitted to a pair of end plugs 40 on which the rotating shaft 35 is supported. The suction pipe 32 has a sliding surface 32b in which a slit-like suction hole 32a is formed to extend upstream in the moving direction of the fiber bundle (fleece) F across the nip point of the bottom nip roller 35a. The winding member 33 has a sliding surface 33 a for slidingly guiding the ventilation apron 34. Then, as shown in FIGS. 2 and 4A, the suction pipe 32 is disposed upstream of the nip point of the bottom nip roller 35a in the moving direction of the fiber bundle F, and the winding member 33 is disposed downstream thereof. Is established.
[0028]
The suction pipe 32 is formed in a shape capable of guiding the ventilation apron 34 to a position near the nip point between the front bottom roller 12 and the front top roller 19. The winding member 33 is provided so that the distance L between the nip point and the position where the fiber bundle F is separated from the ventilation apron 34 downstream of the nip point is 5 mm or more, preferably 8 to 10 mm. The winding member 33 is formed of a bar-like solid body.
[0029]
The ventilation apron 34 is wound around the suction pipe 32, partly on the wrapping member 33, and partly on the bottom nip roller 35a, and the sliding surfaces 32b, 33a are rotated with the rotation of the bottom nip roller 35a. And is rotated while sliding along. In this embodiment, the ventilation apron 34 is formed of a woven cloth that can secure appropriate ventilation.
[0030]
As shown in FIG. 1 and FIG. 2A, a suction of a single type pneumatic device acting to suction the fiber bundle F sent from the draft device 11 at the time of yarn breakage is provided near the lower portion of the winding member 33. The tips of the nozzles 49 are provided respectively. The base end of the suction nozzle 49 is connected to a pneumatic duct 50 common to all weights.
[0031]
Next, the operation of the device configured as described above will be described.
When the spinning machine is operated, the fiber bundle F is drafted by passing between the bottom rollers 12 to 14 and the top rollers 19 to 21 of the draft device 11, and then guided to the fiber bundle collecting device 30. . The top nip roller 31a of the delivery unit 31 is rotated slightly faster than the surface speeds of the front bottom roller 12 and the front top roller 19, and the fiber bundle F is twisted after passing the nip point of the delivery unit 31 with a moderate tension. While moving to the downstream side.
[0032]
The suction action of the duct 44 extends to the suction pipe 32 via the connection pipe 48, and the suction action of the suction hole 32 a formed in the sliding surface 32 b extends to the fiber bundle F via the ventilation apron 34. Then, the fiber bundle F moves to a position corresponding to the suction hole 32a in a state of being collected by suction. Therefore, compared with a spinning machine in which the fiber bundle concentrating device 30 is not provided, generation of fluff and cotton loss are suppressed, and yarn quality is improved.
[0033]
Since the wrapping member 33 provided separately from the suction pipe 32 exists downstream of the suction pipe 32, the fleece angle θ1 shown in FIG. 4A is changed to the wrapping member 33 shown in FIG. Is increased compared to the fleece angle θ2 in the case where there is no. In the state where the fleece angle is large, the distance from the nip point to the separation of the fiber bundle F from the surface of the ventilation apron 34 becomes longer. Therefore, when the fiber bundle is rotated by the twisting action transmitted from the winding portion to the fiber bundle F, the fiber f projecting around the fiber bundle F is rotated while being in contact with the ventilation apron 34. The fibers f are easily twisted into the fiber bundle F, and the generation of fluff is suppressed. Further, as shown in FIG. 5A, in the configuration in which the winding member 33 is present, the fiber bundle F reciprocates so as to roll along the apron. As a result, the fibers f projecting around the fiber bundle F are easily twisted into the fiber bundle F.
[0034]
On the other hand, in a state where the fleece angle is small, the distance from the nip point to the separation of the fiber bundle F from the surface of the ventilation apron 34 is short. Therefore, when the fiber bundle is rotated by the twisting action transmitted from the winding portion to the fiber bundle F, the fiber f projecting around the fiber bundle F is less likely to be rotated in contact with the ventilation apron 34, It is easy to be fluffed without being twisted into the fiber bundle F. Further, as shown in FIG. 5B, in a configuration in which the winding member 33 does not exist and the ventilation apron 34 is wound around the bottom nip roller 35a and the suction pipe 32, the fiber bundle F rolls along the apron. Reciprocate to slide without moving. As a result, the fibers f projecting around the fiber bundle F are less likely to be twisted into the fiber bundle F.
[0035]
Using a spinning machine equipped with the fiber bundle bundling device 30 having the winding member 33 and a spinning machine equipped with the fiber bundle bundling device 30 without the winding member 33, spinning of the 40th yarn is performed. % Was measured. As a result, with respect to U%, the presence of the winding member 33 was somewhat better, but no significant advantage was seen. On the other hand, with regard to the Haininess, clearly better results were obtained when the winding member 33 was present. FIG. 6 shows the results regarding the Hairiness. In addition, "Hairiness" means the total length [cm] of the length of the fluff existing in the length of 1 cm of the yarn. However, no unit is generally added. The average value of Haininess was 3.64 when the winding member 33 was present, and 3.96 when the winding member 33 was not provided. Generally, it is said that the value of Haininess has an advantage when there is a difference of 0.1, and when there is a difference of 0.3 as in this result, it can be said that the effect of suppressing fluff generation is clearly large. . The Haininess of the yarn spun by the spinning machine without the fiber bundle concentrating device 30 was 4.77.
[0036]
Conventionally, it is said that when the fleece angle is increased, the yarn breaks easily. However, when the fiber bundle concentrating device 30 is provided, the fiber bundle F is pulled out from the nip point while being bundled by the suction action of the suction hole 32a, so that the twist by the winding action easily reaches near the nip point. As a result, the yarn strength is increased, and even if the fleece angle is increased, the occurrence of yarn breakage is suppressed. Therefore, a decrease in productivity due to yarn breakage can be suppressed.
[0037]
This embodiment has the following effects.
(1) The fiber bundle concentrating device 30 is rotated in contact with the suction pipe 32 provided on the upstream side in the moving direction of the fiber bundle F with respect to the nip point of the sending section 31 and the sliding surface 32 b of the suction pipe 32. Ventilation apron 34 provided. Further, a wrapping member 33 around which the ventilation apron 34 is wrapped is provided separately from the suction pipe 32 on the downstream side in the moving direction of the fiber bundle F from the suction pipe 32 to increase the fleece angle. Therefore, the action of suppressing the generation of fluff is enhanced, and the generation of fluff is further suppressed, and the yarn quality is improved. Further, even if the fleece angle is increased, the fiber bundle F is pulled out from the nip point in a state of being bundled by the suction action of the suction holes 32a, so that the twist by the winding action reaches near the nip point, and the occurrence of yarn breakage increases. Is suppressed.
[0038]
(2) The winding member 33 is provided so that the distance between the nip point of the delivery unit 31 and the position where the fiber bundle is separated from the ventilation apron 34 downstream of the nip point is 5 mm or more. Therefore, while the fiber bundle F moves while rolling on the ventilation apron 34, the fiber f floating from the fiber bundle F is easily twisted into the fiber bundle F, and the action of suppressing the generation of fluff is improved.
[0039]
(3) The suction pipe 32 and the wrapping member 33 around which the ventilation apron 34 is wrapped are supported on the supported portion (end plug 40) which is detachably supported by the support portions 15a and 38a provided on the machine frame. At least one end is supported in a fitted state. Therefore, it is easy to arrange the suction pipe 32 and the wrapping member 33 so that the distance is 5 mm or more.
[0040]
(4) The winding member 33 is formed of a bar-like solid body. Therefore, as compared with the case where the winding member 33 is formed in a tubular shape, the manufacturing is simplified, and even if the winding member 33 collides with another member at the time of assembling or disassembling maintenance work, it is hard to be damaged.
[0041]
(5) The pressing force of the top nip roller 31a against the ventilation apron 34 is carried by the bottom nip roller 35a, and the pressing force of the top nip roller 31a does not act on the suction pipe 32. Therefore, the suction pipe 32 does not require rigidity as compared with the conventional device (Patent Document 3), and can secure sufficient strength even if it is made of resin.
[0042]
(6) The duct 44 as a negative pressure source is provided independently of the pneumatic device that functions to suck the fleece sent from the draft part when the yarn breaks. Therefore, it is easy to adjust the suction pressure of the suction pipe 32 to an appropriate pressure.
[0043]
The embodiment is not limited to the above, and may be configured as follows, for example.
○ If the distance L from the nip point of the delivery section 31 to the position where the fiber bundle F is separated from the ventilation apron 34 downstream of the nip point of the delivery section 31 is 5 mm or more, the effect of suppressing the generation of fluff becomes good, and the distance L Is not particularly limited. However, if the length is too long, the effect of suppressing fluff is not significantly improved, and the size of the machine is increased.
[0044]
The delivery unit of the fiber bundle concentrating device 30 is not limited to the configuration including the nip roller pair. For example, as a configuration for driving the ventilation apron 34, the suction pipe 32 and the bottom nip roller 35a are eliminated, a suction pipe having an oval cross section is provided, and a suction hole is formed at a predetermined position of the suction pipe. A ventilation apron 34 is slidably wound around the outer periphery of 33. Then, the top nip roller 31a may be driven positively, and the top nip roller 31a may be driven while being pressed against the ventilation apron 34 to drive the ventilation apron 34. In this case, the winding member 33 can have a function of adjusting the tension of the ventilation apron 34.
[0045]
The suction pipe 32, the wrapping member 33, and the rotating shaft 35 are not limited to the configuration in which four weights are one unit, but the number of weights (for example, eight weights) between the roller stands 15 is one unit, and two weights are one unit. A configuration may be adopted. Also, not all units need to have the same number of weights, and the number of weights between the roller stands 15 may be divided into different numbers (for example, 6 weights and 2 weights), and two types of units may be provided correspondingly.
[0046]
O Instead of forming the winding member 33 with a solid body, it may be formed in a tubular shape. If it is tubular, it will be lightweight.
〇 The suction pipe 32 may be formed in a shape whose end is closed. In this case, the end plug 40 does not care to seal the end of the suction pipe 32, and the fitting hole in which the bearing 39 is fitted and the fitting in which the ends of the suction pipe 32 and the winding member 33 are fitted. Since it is sufficient to adopt a configuration having a joint (hole), manufacturing is simplified.
[0047]
The suction pipe 32 and the wrapping member 33 may be configured so that the end opposite to the side fitted to the end plug 40 is fitted to a connection member connectable to the connection pipe 48.
[0048]
Instead of providing a plurality of ducts 44 along the longitudinal direction of the spinning frame, only one duct 44 may be provided over the entire length of the spinning frame.
The position of the duct 44 is not limited to the upper rear side of the draft device 11, but may be disposed behind the draft device 11 or lower rear portion of the draft device 11.
[0049]
○ Instead of sharing the ducts 44 with the suction pipes 32 arranged on both the left and right sides of the spinning machine, the ducts 44 may be divided into right and left ones and arranged in two rows along the longitudinal direction of the spinning frame. .
[0050]
The configuration of the suction device is not limited to the configuration in which the fan 47a is driven by the motor 47. For example, a vacuum pump (vacuum pump) may be used. The vacuum pump may be a rotary pump or a reciprocating pump.
[0051]
The ventilation apron 34 may be formed of a knitted fabric instead of a woven fabric. Also in this case, a suitable air permeability can be obtained without taking the trouble of opening a small hole in the belt constituting the ventilation apron 34 as in the case of the woven fabric, and the ventilation apron 34 can be manufactured at low cost. Further, due to the elasticity of the knitted fabric, the ventilation apron 34 is rotated in an appropriate tension state without particularly providing a tension device.
[0052]
Instead of forming the ventilation apron 34 with a woven cloth or a knitted fabric, a rubber or elastic resin belt may be formed with a large number of holes.
The rotary shaft 35 on which the bottom nip roller 35a is formed is a common shaft, and is driven by a motor via a gear train provided at the gear end of the machine base, similarly to the bottom rollers 12 to 14 of the draft device 11. It may be configured.
[0053]
The negative pressure source of the suction pipe 32 and the negative pressure source of the pneumatic device may be shared.
フ A flute type configuration may be adopted instead of a single nozzle type as a pneumatic device.
[0054]
The invention (technical idea) grasped from the embodiment will be described below.
(1) In the invention described in claim 2, the distance is not less than 8 mm and not more than 10 mm.
[0055]
(2) A ring spinning machine comprising the fiber bundle concentrating device according to any one of claims 1 to 4 and the technical idea (1).
[0056]
【The invention's effect】
As described above in detail, according to the first to fourth aspects of the present invention, the generation of fluff can be suppressed with a simple configuration and the yarn quality can be improved by using a conventional fiber bundle concentrator.
[Brief description of the drawings]
FIG. 1 is a partially cutaway schematic side view showing a fiber bundle concentrating device according to an embodiment.
2A is a partial schematic view of the fiber bundle concentrator viewed from the front in a fiber bundle moving direction, and FIG. 2B is a front view of a rotating shaft.
FIG. 3 is a partially enlarged view of FIG. 1;
FIG. 4A is a schematic diagram illustrating an operation when there is a wrapping member, and FIG. 4B is a schematic diagram illustrating an operation when there is no wrapping member.
FIG. 5A is a schematic perspective view illustrating an operation when there is a wrapping member, and FIG. 5B is a schematic perspective view illustrating an operation when there is no wrapping member.
FIG. 6 is a graph showing the measurement results of Haininess.
FIG. 7 is a schematic side view of the prior art.
FIG. 8 is a schematic side view of another prior art.
[Explanation of symbols]
F: Fiber bundle, L: Distance, θ1, θ2: Fleece angle, 11: Draft device as draft part, 15: Roller stand constituting machine frame, 15a, 38a: Support, 30: Fiber bundle bundling device, Reference numeral 31 denotes a delivery unit, 31a: a top nip roller as a nip roller constituting the delivery unit, 32: a suction pipe as a suction unit, 32a: a suction hole, 32b, 33a: a sliding surface, 33: a winding member, 34: a ventilation apron. , 35a... Bottom nip rollers as nip rollers constituting the sending section.

Claims (4)

What is claimed is: 1. A fiber bundle bundling device for bundling a fiber bundle drafted by a draft part of a spinning machine, comprising: a delivery part provided downstream of a final delivery roller pair of the draft part and having a nip roller; and a nip point of the delivery part. And a suction unit having a slide surface provided with a suction hole provided to extend upstream in the moving direction of the fiber bundle, and the delivery unit is configured to be rotated while being in contact with the slide surface. The spinning machine further includes a winding member around which the ventilation apron is wound separately from the suction unit on the downstream side in the moving direction of the fiber bundle from the suction unit to increase the fleece angle. Fiber bundle focusing device. The fiber in the spinning machine according to claim 1, wherein the winding member is provided such that a distance from the nip point to a position where the fiber bundle is separated from the ventilation apron on the downstream side of the nip point is 5 mm or more. Bundle focusing device. The suction portion around which the ventilation apron is wound and the winding member are supported in a state where at least one end is fitted to a supported portion which is detachably supported on a support portion provided on the machine frame. A fiber bundle concentrating device in the spinning machine according to claim 2. The fiber bundle concentrating device in a spinning machine according to any one of claims 1 to 3, wherein the winding member is formed of a bar-shaped solid body.

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