Dust-removing mechanism in open-end spinning frame

A dust-removing mechanism in an open-end spinning frame has a dust-removing chamber into which a dust-removing opening opens, the dust-removing opening being defined by a rear wall disposed upstream in the direction of rotation of the combing roller and having an edge and a front wall disposed downstream in the direction, there being an angle .alpha. formed between first and second lines passing through the front and rear wall edges and the center of the combing roller, an angle .beta. formed between a third line passing through the center of the combing roller and the center of an opening in the rotor and a fourth line passing through the center of the combing roller perpendicularly to the third line, an angle .UPSILON. formed between a surface of the front wall and a fifth line extending parallel to the fourth line through the front wall edge, and an angle .delta. formed between a surface of the rear wall and a sixth line extending parallel to the fourth line through the rear wall edge, the angles being in the following ranges: EQU 40.degree..ltoreq..alpha..ltoreq.45.degree. EQU 0.degree..ltoreq..beta..ltoreq.5.degree. EQU 40.degree..ltoreq..UPSILON..ltoreq.45.degree. EQU 0.degree..ltoreq..delta..ltoreq.20.degree..

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a dust-removing mechanism in an open-end 
spinning frame. 
2. Description of the Prior Art 
FIG. 1 of the accompanying drawings illustrates a conventional open-end 
spinning frame. A sliver A as it is introduced into a spinning unit 1 is 
advanced while being sandwiched between a feed roller 2 and a presser 3, 
and is separated into fibers by a combing roller 4 which rotates at a high 
speed that is surrounded by an outer wall 20 extending along the outer 
peripheral surface of the combing roller 4 with a predetermined clearance 
therebetween. The separated fibers are then transferred in the direction 
of the arrow along the circumferential surface of the combing roller 4 
into a fiber feed channel 5. The fibers as they emerge from the fiber feed 
channel 5 are carried on a current of air and rotated at a high speed, and 
then are deposited on an inner peripheral surface of a rotor 6 in which a 
vacuum is developed. The fibers are thereafter pulled as a yarn out of a 
yarn delivery passage (not shown), and the yarn is wounded on a bobbin to 
form a yarn package. 
The outer wall 20 has an opening 21 through which the circumferential 
surface of the combing roller 4 is partially exposed to a dust-removing 
chamber 7 disposed adjacent to the combing roller 4. Impurities and 
foreign matter B such as leaf pieces and neps, for example, in the sliver 
are discharged through the opening 21 into the dust-removing chamber 5 
under centrifugal forces of the combing roller 4 as it separates the 
sliver. Other impurities and foreign matter B such for example as short 
fibers, waste cotton, and dust are separated from the surface of the 
combing roller 4 by an air stream produced by the rotation of the latter 
and then are discharged into the dust-removing chamber 7. The 
dust-removing chamber 7 has a small air inlet 7a in one end thereof, but 
is of a substantially closed construction. The other end of the 
dust-removing chamber 7 has an outlet 7b connected to a trash pipe 8 for 
delivering the impurities B. The trash pipe 8 is coupled to a side of a 
dust collector duct 9 which is shared by other spinning units. The dust 
collector duct 9 leads through an air blower 10 to a dust collector 
chamber (not shown). The impurities B separated and discharged into the 
dust-removing chamber 7 are discharged therefrom into the trash pipe 8 on 
a suction stream of air created by the action of the air blower 10, and 
then are collected through the dust collector duct 9 into the dust 
collector chamber. 
The conventional dust-removing mechanism of the foregoing construction has 
suffered from the following shortcoming: As described above, the 
impurities B are carried on a current of air from the dust-removing 
chamber 7 into the trash pipe 8. Since it is necessary to develop a 
relatively strong suction air stream in the dust-removing chamber 7 for 
delivery of the impurities B, the dust-removing chamber 7 is of 
substantially closed construction. Therefore, a suction force due to the 
vacuum in the rotor 6 tends to be developed in the dust-removing chamber 
7. This suction force is liable to cause the impurities B once separated 
from the fibers to be drawn back into the rotor 6 on a suction air stream 
generated by the latter, and to be deposited in the rotor 6. One solution 
to avoid such an undesirable phenomenon would be to increase the speed of 
air flow in the dust-removing chamber 7. However, such an air flow would 
peel not only the impurities but longer fibers off the surface of the 
combing roller 4, resulting in a poorer yarn yield. The outlet 7b of the 
dust-removing chamber 7 is constricted for increasing the speed of air 
flow and hence tends to get clogged with the impurities B passing 
therethrough. 
SUMMARY OF THE INVENTION 
It is an object of the present invention to provide a dust-removing 
mechanism for open-end spinning frames which has a dust-removing chamber 
vented to atmosphere for effective separation of impurities from a combing 
roller substantially without depending on a suction current of air, and 
which delivers out the separated impurities on an air stream or other 
means such as a conveyor. 
Another object of the present invention is to provide a dust-removing 
mechanism having a large dust-removing opening and capable of separating 
impurities only, without discharging yarn-forming fibers. 
According to the present invention, there is provided a dust-removing 
mechanism in an open-end spinning frame having a rotor, including a 
combing roller for separating a supplied sliver into fibers, an outer wall 
surrounding the combing roller and having a dust-removing opening, and a 
dust-removing chamber into which the dust-removing opening opens, so that 
impurities will be separated from the sliver by the combing roller and 
discharged through the dust-removing opening into the dust-removing 
chamber, wherein the improvement comprises a rear wall disposed upstream 
in the direction of rotation of the combing roller and having an edge and 
a front wall disposed downstream with respect to the direction of combing 
roller rotation, the front and rear wall edges jointly defining the 
dust-removing opening, there being an angle .alpha. formed between first 
and second lines passing through the front and rear wall edges and the 
center of the combing roller, an angle .beta. formed between a third line 
passing through the center of the combing roller and the center of an 
opening in the rotor and a fourth line passing through the center of the 
combing roller perpendicularly to the third line, an angle .UPSILON. 
formed between a surface of the front wall and a fifth line extending 
parallel to the fourth line through the front wall edge, and an angle 
.delta. formed between a surface of the rear wall and a sixth line 
extending parallel to the fourth line through the rear wall edge, the 
angles being in the following ranges: 
EQU 40.degree..ltoreq..alpha..ltoreq.45.degree. 
EQU 0.degree..ltoreq..beta..ltoreq.5.degree. 
EQU 40.degree..ltoreq..UPSILON..ltoreq.45.degree. 
EQU 0.degree..ltoreq..delta..ltoreq.20.degree. 
The above and other objects, features and advantages of the present 
invention will become more apparent from the following description when 
taken in conjunction with the accompanying drawings in which preferred 
embodiments of the present invention are shown by way of illustrative 
example.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
As shown in FIG. 2, a spinning unit 1 to which the principles of the 
present invention are applicable includes combing roller 4 having a 
central axis 4a and a rotor 6 having a central axis 6a intersecting the 
central axis 4a at the center of the combing roller 4. 
The combing roller 4 is surrounded by an outer wall 20 having a 
dust-removing opening 21 defined by a rear wall 22 disposed upstream in 
the direction (indicated by the arrow) of rotation of the combing roller 4 
and a front wall 23 disposed downstream in the same direction. The 
dust-removing opening 21 communicates with an open-type dust-removing 
chamber 7 which is vented to atmosphere through an apertured plate or 
screen 11 (FIG. 4) covering the dust-removing chamber 7. Impurities B 
separated and discharged into the dust-removing chamber 7 fall onto a 
conveyor 24 positioned in the dust-removing chamber 7, and are delivered 
thereby in the direction of the arrow into a dust collector duct (shown at 
9 in FIG. 1), from which they are carried on an air current into a dust 
collector chamber. Any suction current of air produced by an air blower 
(shown at 10 in FIG. 1) does not affect the dust-removing opening 21, and 
the air flow in the dust-removing chamber 7 remains substantially 
undisturbed by the suction air stream caused by the rotor 6. 
With a conventional closed-type dust-removing chamber disclosed in Japanese 
Laid-Open Patent Publication No. 51-1732, the dust-removing capability is 
controlled by an angle .UPSILON.' formed between the front wall 23 and a 
line passing through an edge of the front wall 23 and the center 4a of the 
combing roller 4. For open-type dust-removing chambers, however, it has 
been found that the dust-removing capability is also affected by an 
opening angle .alpha., and the positions and inclinations of the front and 
rear walls. 
More specifically, a consideration of dust-removing mechanisms in open-end 
spinning frames requires study of the behavior of currents of air in the 
area of the dust-removing opening. The study by the inventors has revealed 
that there are basically three currents of air involved in the 
dust-removing opening. One of the three currents of air is a suction 
current of air S produced by the rotation of the rotor 6 and directed 
toward the rotor 6 in the vicinity of the edge 23a of the front wall 23. 
The second air current is a stream of air t accompanying the rotating air 
flow along the outer peripheral surface of the combing roller 4. The third 
air current is a supplementing air flow u generated when the rotating air 
flow around the combing roller 4 is peeled off as a boundary layer, the 
supplementing air flow u being largely dependent on the shape of the 
dust-removing opening 21. 
The components of the fibers separated by the combing roller 4 are divided 
into several groups according to form and gravity, and move on the 
rotating air flow between the combing roller 4 and the outer wall 20. When 
the fibers reach the dust-removing opening 21, relatively heavy seed 
pieces and neps fly out into the dust-removing chamber 7 under central 
forces. Those fibers which have large surface areas and a small apparent 
specific gravity remain trapped in the rotating air flow and move 
therewith. Other impurities B such as trash and dust, for example, having 
an intermediate specific gravity are displaced slightly radially outwardly 
into the accompanying air current t. For increased dust-removing 
capability, it is required that the accompanying air current t be spread 
in the dust-removing chamber 7 to discharge the impurities B such as trash 
and dust. If the dust-removing opening 21 were too small, the suction air 
current S would be too intensive to allow the accompanying air current t 
to be spread out since the latter would be repelled by the suction air 
current S and absorbed into the rotating air flow again. 
As the dust-removing opening 21 is larger, the accompanying air flow t 
would be spread well for improved dust-removing capability. If the 
dust-removing opening 21 were too large, however, the rotating air flow 
would be peeled off as the boundary layer at an increased rate, with the 
result that the fibers would be disoriented and the supplementing air flow 
u would become stronger. The impurities once discharged would then be 
carried by the supplementing air flow u, join the rotating air flow and 
the suction air flow S, and be deposited in the rotor 6. Accordingly, 
there is a preferred range for the size of the dust-removing opening 21. 
In the following description, the size of the dust-removing opening 21 is 
defined by an opening angle .alpha., as shown in FIG. 3, which is formed 
between a line passing through the center 4a of the combing roller 4 and 
the edge 23a of the front wall 23 and a line passing through the center 4a 
and an edge 22a of the rear wall 22. 
If the front wall edge 23a were displaced downstream for enlarging the 
dust-removing opening 21, the suction force caused by the rotor 6 would 
become more influential and the suction air current S would be increased. 
The impurities displaced into the accompanying air current t and tending 
to be separated from the rotating air flow would be blocked by the suction 
air current S and become more likely to join the rotating air flow. 
Therefore, there is a limitation on the position of the front wall edge 
23a in the upstream direction. In the following description, the position 
of the front wall edge 23a is defined by an angle .beta., as shown in FIG. 
3, formed between a line I passing through the center 4a of the combing 
roller 4 perpendicularly to a line connecting between the centers 6a, 4a 
of an opening in the rotor 6 and the combing roller 4, and a line II 
passing through the center 4a of the combing roller 4 and the front wall 
edge 23a. 
If the angle of inclination of the front wall 23 were too large, then the 
rotating air flow caused by the rotation of the combing roller 4 would be 
peeled off by the edge 23a, disturbing the fibers and resulting in a loss 
of fibers. If the front wall 23 is inclined at a proper angle, then it 
allows the rotating air flow to move smoothly, and the accompanying air 
current t becomes a laminar flow along the front wall 23 for good dust 
removal. If the angle of inclination were too small, the rotating air flow 
and the accompanying air current t would impinge on the front wall 23, 
producing swirls which would be carried on the suction air current S to 
permit the separated impurities to be absorbed again into the rotor 6. 
Accordingly, it is expected that there is a preferred range of angles of 
inclination of the front wall 23. 
The angle of inclination of the front wall 23 is defined by an angle 
.UPSILON. formed between a line III parallel to the line I and the surface 
of the front wall 23. 
The position of the edge 22a of the rear wall 22 is directly related to the 
size of the dust-removing opening 21, and the edge 22a has the same 
function as that of the front wall edge 23a. 
If the angle of inclination of the rear wall 22 were too large, the 
accompanying air current t produced by the rotation of the combing roller 
4 would easily be dispersed for increased dust removal efficiency, but the 
supplementing air current u for compensating for a boundary layer 
separation would be increased and the impurities to be absorbed again into 
the rotor 6 would be increased, resulting in a poorer yarn quality. If the 
angle of inclination of the rear wall 22 were too small, it would become 
difficult for the accompanying air current t to be dispersed, lowering the 
dust removal efficiency. Therefore, there is a proper rear wall position 
and a proper angle of inclination of the rear wall 22. In the following 
description, the angle of inclination of the rear wall 22 is defined by an 
angle .delta. formed between a line IV parallel to the line I and the 
surface of the rear wall 22. 
According to the present invention, it is required that the edge 23a of the 
front wall 23 be positioned on the line I or upstream of the line I, and 
the angle .beta. be in the range of from 0.degree. to 5.degree.. It is 
preferred that the angle .alpha. of the dust-removing opening 21 be in the 
range of from 40.degree. to 45.degree.. 
It is also preferred that the angle .UPSILON. of inclination of the front 
wall 23 be in the range of from 40.degree. to 45.degree. and the angle 
.delta. of inclination of the rear wall 22 be in the range of from 
0.degree. to 20.degree.. 
The advantages of the present invention will appear clear from the 
following example: 
EXAMPLE 
Using the spinning unit as shown in FIG. 2 with dimensions varied, spinning 
operations were effected under the following spinning conditions: 
Sliver supplied: 
Material: Cotton 100% 
Fineness: 4.3 g/in. 
Average fiber length: 23 mm 
Grain: 420 gr/6 yd 
Sliver U%: 4.0% 
Trash content: 250 mg/kg 
Spinning condition: 
Spinning time: 8 H 
Yarn count: 7' S 
Twist constant: 4.8 
Rotor RPM: 60,000 rpm 
Combing roller RPM: 8,000 rpm 
The quality of yarns produced is evaluated according to U%, and the dust 
removal efficiency is evaluated according to the amount of dust deposited 
in the rotor. The results are shown in the following table: 
TABLE 
__________________________________________________________________________ 
No. 
Items 1 2 3 4 5 6 7 8 9 10 11 12 
Remarks 
__________________________________________________________________________ 
Inventive device 
x O O O x O O O x x x x No. 12 = closed 
(marked with O) dust-removing 
Dust- .alpha..sup.o 
35 40 
45 
45 
45 45 
40 
45 
55 55 45 35 
chamber 
removing 
.beta..sup.o 
5 5 5 0 5 5 5 0 5 10 -5 5 (suction pressure 
chamber 
.gamma..sup.o 
40 40 
45 
40 
45 45 
45 
45 
45 40 40 40 
= 110 mmAg) 
dimensions 
.delta..sup.o 
0 5 10 
0 -20 
0 20 
20 
0 0 0 0 
Amount of depo- 
1.5 
0.4 
0.3 
0.7 
1.4 
0.6 
1.5 
0.3 
2.5 
0.9 
1.7 
1.3 
sit in rotor mg/kg 
U Start 
9.8 
9.8 
9.8 
9.8 
10.1 
9.8 
9.8 
9.7 
13.2 
10.7 
10.1 
9.8 
% End 
10.0 
9.8 
9.8 
9.8 
10.4 
9.8 
9.8 
9.7 
13.9 
10.9 
10.6 
9.9 
__________________________________________________________________________ 
As is apparent from the above table, the amounts of deposited dust in the 
rotor after 8 hours of operation of the spinning unit equipped with the 
dust-removing chamber according to the present invention are all below 1.0 
mg/kg, and therefore the dust-removing chamber of the invention has an 
excellent dust removal efficiency. The U% of the spun yarns is 10% or 
below, and hence the dust-removing mechanism of the invention achieves a 
good yield of fibers of good quality. 
With the arrangement of the present invention, the dust-removing chamber is 
of the open type vented to atmosphere, and hence is free from a reduced 
dust removal efficiency and a poor yarn yield due to mutual interaction of 
air currents in the dust-removing chamber. The dimensions and angles of 
the dust-removing chamber are selected to be optimum so that yarns can be 
spun under good conditions for stable yarn spinning operation. 
While in the embodiment of FIG. 2 the conveyor 24 is employed for 
discharging the impurities B, an opening 12 and a confronting suction 
inlet 13 may be provided in a lower portion of the dust-removing chamber, 
as shown in FIG. 4, for delivering dust on an air stream. Since the 
dust-removing chamber is open to atmosphere, the air stream flowing 
through the opening 12 and the suction inlet 13 is under a low pressure, 
and therefore does not adversely affect the dust removal operation. 
In the illustrated embodiment, the combing roller 4 has a vertical central 
axis. However, the combing roller 4 may be arranged such that its central 
axis extends horizontally. The rotor 6 according to the foregoing 
embodiment is of the self-discharge type having an air-discharging hole. 
However, the present invention is also applicable to a rotor of the 
forced-discharge type having no air-discharging hole. 
Although certain preferred embodiments have been shown and described, it 
should be understood that many changes and modifications may be made 
therein without departing from the scope of the appended claims.