Apparatus for treatment

An apparatus for treating textile materials has an impeller or vane wheel which is disposed in a flow passageway communicating with a circulatory pump and with the interior of a perforated cylindrical beam and which is connected to a shaft of the beam.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to an apparatus for treatment, such as dyeing 
and bleaching, of textile materials wound on a perforated cylindrical 
beam, and more particularly to an improved drive mechanism for rotating 
the beam. 
2. Description of the Prior Art 
There are known a variety of apparatus for forcing treatment liquid, such 
as dyeing and bleaching liquid, into and through textile materials such as 
yarns, tapes and fabrics that are wound on a rotating perforated cylinder 
commonly known as "beam". In an example disclosed in Japanese Utility 
Model Post-Examination Publication No. 43-18782, an axial shaft of the 
beam is connected to a driving shaft disposed outside a treatment vessel 
of the apparatus for rotation of the beam. In another example disclosed in 
Japanese Patent Post-Examination Publication No. 44-3252, a gear mounted 
on a support frame of the beam meshes with another gear mounted on a 
driving shaft extending into a treatment vessel from the outside for 
rotation of the beam support frame. Difficulties have been experienced 
with such prior treatment apparatus in that since the driving shaft must 
extend into the treatment vessel from outside and since the vessel is 
maintained interiorly in very high pressure condition, it is required to 
seal about the driving shaft so as to maintain the interior of the vessel 
at high pressure during the treating. A drive means such as a motor or a 
speed reducer is also required. Moreover, it is required to take measures 
for safety against the strain on the driving shaft resulting from any 
abnormal rotation, thus increasing the costs of installation and 
maintenance. 
SUMMARY OF THE INVENTION 
It is therefore an object of the present invention to provide an apparatus 
for treating textile materials in which apparatus a perforated cylindrical 
beam is rotated by utilizing the liquid flow pressure of a circulatory 
pump, thus requiring not only so special sealing measure for high 
pressure, but also no drive mechanism outside a treatment vessel of the 
apparatus. 
According to the present invention, an apparatus for treating textile 
materials has an impeller or vane wheel which is disposed in a flow 
passageway communicating with a circulatory pump and with the interior of 
a perforated cylindrical beam and which is connected to a shaft of the 
beam. 
Many other advantages, features and additional objects of the present 
invention will become manifest to those versed in the art upon making 
reference to the detailed description and the accompanying drawings in 
which a preferred structural embodiment incorporating the principles of 
the present invention is shown by way of illustrative example.

DETAILED DESCRIPTION 
FIG. 1 shows an apparatus for treating, such as dyeing or bleaching, 
textile materials 67. The apparatus generally comprises a cylindrical 
vessel 1 having a generally circular cross-section (FIGS. 2 and 3) and 
extending along a generally horizontal axis. The vessel 1 is covered at 
one or front end tightly by an openable front lid plate 2 and at the other 
or rear end by an annular rear lid plate 3 and an annular frustoconical 
cover plate 4 (defining a liquid flow passageway 33 as described below). 
A perforated cylindrical beam 5 having a substantially circular cross 
section is supported within the vessel 1 coaxially thereof. The beam 5 is 
adapted to support the materials 67 to be treated, the materials 67 being 
wound on the periphery of the beam 5. The beam 5 has a multiplicity of 
holes 66 formed in the periphery of the beam and distributed uniformly 
therearound, allowing treatment liquid to flow into and through the 
materials 67 wound on the beam. 
As shown in FIG. 2, the beam 5 is supported at each end by a truck 10 which 
has on its underside a pair of wheels 11, 12 rollable on and along a pair 
of parallel spaced rails 6, 7 secured to and extending longitudinally of 
the vessel 1. The truck 10 also has a pair of rollers 8, 9 rotatably 
mounted on a pair of upwardly directed arms 10a, 10b by means of a pair of 
pivot pins 13, 14, respectively. The beam 5 rests on the two pairs of 
rollers 8, 9; 8, 9 so that the beam 5 is rotatable about a shaft 48 
extending axially thereof. As the beam 5 is rotated clockwise, i.e. in the 
direction of an arrow A by a drive mechanism (described below), the 
rollers 8, 9 roll on the periphery of the beam 5, during which time each 
roller 8, 9 is rotated counterclockwise about the respective pivot pin 13, 
14. 
As shown in FIG. 1, on the inner surface of the rear lid plate 3 an annular 
retainer 15 is mounted in which a ring 16 is rotatably received via a 
slide member 17 of fluorocarbon resin. The ring 16 is partly received in 
an annular peripheral recess 18 formed at the rear end of the beam 5. 
On the other hand, a nut 19 is mounted on the front lid plate 2 coaxially 
of the beam 5. A pusher bolt 20 threadedly extends through the nut 19 for 
axial movement. A pusher disk 21 is rotatably mounted on one end (adjacent 
to the beam 5) of the pusher bolt 20 via a bearing 22 so as not to move 
axially of the bolt 20. The pusher disk 21 has a peripheral edge 23 which 
is engageable with an annular peripheral projection 24 formed at the front 
end of the beam 5. A handle 29 is mounted on the other end (remote from 
the beam 5) of the pusher bolt 20 for rotating the pusher bolt 20. As the 
pusher bot 20 is rotated in one direction by the handle 29, the pusher 
bolt 20 is moved toward the beam 5 to bring the peripheral edge 23 of the 
pusher disk 21 in contact with the annular peripheral projection 24, thus 
urging the rear end of the beam 5 against the ring 16. 
The peripheral edge 26 of the front lid plate 2 is fluidtightly fastened to 
the front peripheral edge 27 of the vessel 1 by means of an annular clasp 
28. Designated by 30 is a sealing ring which is mounted within the nut 30 
coaxially thereof to effect a fluidtight seal between the nut 30 and the 
pusher bolt 20. Designated by 31 is a sealing cap covering the outer or 
front end of the nut 19 to assist in fluidtightly sealing. 
The flow passageway 33 that is defined by the annular frustoconical plate 4 
communicates at one end with the interior of the beam 5 via a central 
opening 32 of the annular rear lid plate 3 and at the other end with a 
liquid flow passageway 37 at the outlet side of a pump 38 via a liquid 
flow passageway 36 defined by a casing 34 and a liquid flow passageway 37 
defined by a pipe 35. 
A liquid flow passageway 40 at the inlet side of the pump 38 communicates 
with a pair of liquid flow passageways 44, 45 via a heater 41 and a 
connecting pipe 42. Through the flow passageways 44, 45, the treatment 
liquid is returned from the bottom portion 43 of the vessel 1 to the pump 
38. 
As shown in FIGS. 1 and 3, a support framework 46 in the shape of a 
steering wheel is mounted in the central opening 32 of the annular rear 
lid plate 3 and extends transversely across the flow passageway 33. The 
support framework 46 has a hub at which the shaft 48 is rotatably 
supported via a bearing 47 in alignment with the axis of the beam 5 as set 
in position by the pusher bolt 20. 
As shown in FIG. 1, the shaft 48 extends into the casing 34 and is 
supported at its rear end 49 by another support framework 50 via a bearing 
51. The support framework 50 has a shape similar to the shape of the 
first-named support framework 46. 
Most important, an impeller or vane wheel 52 (FIGS. 1 and 4) is fixedly 
mounted on the shaft 48 and is disposed in the flow passageway 36 defined 
by the casing 34, for a purpose described below. 
The casing 34 is a double structure having an inner casing 53 surrounding 
the impeller 52 so as to define a bypass passageway 54 around the flow 
passageway 36. The bypass flow passageway 54 opens to the flow passageway 
33, but does not open to the flow passageway 37. 
The bypass passageway 54 also opens to a branch passageway 56 (FIG. 1) 
instead of the flow passageway 37, the branch passageway 54 being defined 
by a branch pipe 56 subdivided from the pipe 35. In the branch pipe 56, a 
valve 57 is mounted for regulating the amount of liquid flow passing 
through the branch pipe 56, for a purpose described below. 
The front end portion of the shaft 48 extends into the beam 5. A drive arm 
59 is fixedly mounted on the distal front end 58 of the shaft 48 and 
extends radially outwardly and terminates short of the inner surface of 
the beam 5. The beam 5 has a projection 60 mounted on the inner surface of 
the beam 5 and extends radially inwardly therefrom for engagement with the 
free end of the drive arm 59. 
Designated by the numeral 61 in FIG. 1 is a safety unit including a safety 
valve 62, a pressure gage 63, and a deaerator 64. Designated by 65 is a 
pulley which is mounted on a shaft of the pump 38 and which is driven by a 
non-illustrated motor via a non-illustrated endless belt. 
In operation, after the beam 5 around which a predetermined amount of 
textile materials 67 is mounted has been installed in position in the 
vessel 1 as mentioned above, the apparatus is filled with treatment 
liquid. As the liquid in the apparatus is circulated by the pump 38 under 
a predetermined air pressure, the liquid from the flow passageway 39 at 
the outlet side of the pump 38 flows into the flow passageway 36 via the 
flow passageway 37, the flow passageway 36 being surrounded by the inner 
casing 53. 
In the inner casing 53, this liquid flow pressure causes the impeller 52 to 
rotate so that the drive arm 59 is angularly moved clockwise, i.e. in the 
direction of an arrow A in FIG. 2. Thus the beam 5 is rotated in the same 
direction as the projection 60 is pushed by the drive arm 59. 
After having caused rotation of the impeller 52, the liquid from the flow 
passageway 33 flows into the interior of the beam 5 in the direction of an 
arrow B, and it then flows through the peripheral holes into the textile 
materials 66 in the direction of an arrow C. 
Finally, the liquid having penetrated the textile materials 67 returns to 
the inlet side of the pump 38 via the passageways 44, 45, the connecting 
pipe 42, and the heat exchanger 41. 
The rotations per minute (r.p.m.) of the shaft 48 can be controlled by 
regulating the amount of the liquid flow from the branch pipe 56 to the 
bypass flow passageway 54 by means of the valve 57. 
A mechanism for transmitting the rotation of the shaft 48 to the beam 5 may 
be any other type. 
The pump 38 may be rotatable in opposite directions; while the pump 38 
rotates in one direction, the liquid flows as described above. While the 
pump 38 rotates in the reverse direction, the liquid then flows in the 
reverse direction so that the impeller 52 is also rotated in the reverse 
direction. 
The number of rotations (r.p.m.) of the beam 5 may be detected by counting 
the number of rotations of the shaft 48 in a known manner. In an example, 
as shown in FIG. 1, a permanent magnet 68 is mounted on the pusher disk 
21, and a magnetic sensor 69 is mounted on the outer surface of the front 
lid plate 2. With this arrangement it is unnecessary to form an aperture 
in the vessel 1 for the purpose of detection, thus guaranteeing an 
adequate degree of fluidtight sealing. 
According to the present invention, since the shaft of the beam is driven 
by the impeller which is rotatable by the liquid flow pressure by the 
pump, the rotation transmitting mechanism can be mounted within a 
fluidtightly sealed space in the vessel. 
Further, it is possible to control the rate of rotation of the impeller by 
a simple bypass means. 
Although varius minor modifications may be suggested by those versed in the 
art, it should be understood that I wish to embody within the scope of the 
patent warranted hereon, all such embodiments as reasonably and properly 
come within the scope of my contribution to the art.