[0001] The invention relates to a method of allowing a tuck-in device of a shuttleless loom
inoperative in response to an instruction from a loom and the tuck-in device.
[0002] JP-A 2001-159053 (first prior art) discloses a weft holding device of a tuck-in device.
The weft holding device of the tuck-in device injects air form a tuck-in nozzle (release
port) provided inside a slit of a block body which leaves open in three directions
at the stoppage time of a weft, thereby removing the weft from a cutting area of a
cutter to prevent the weft from being cut so that a weft end is not tucked in a shedding
of a warp.
[0003] According to the device of the first prior art, even if a signal representing injection
of air from the tuck-in nozzle is outputted in response to a weft cut detection signal,
it takes time when the closing valve actually operates to inject air, so that the
weft stays in a cutting area when the cutter operates, and hence the weft is cut.
Accordingly, there occurs that the weft is tucked in the shedding of the warp by the
injection of air through another tack-in nozzle (guide hole).
[0004] Further, JP-A 3-113051 (second prior art) discloses a technique relating to a method
of and a device for performing tuck-in operation in a shuttleless loom. According
to this technique, a weft end is gripped and tucked in by a needle, wherein a weft
is disposed within an operation area of the needle by injecting air at the stoppage
time of the loom other than a weft stoppage, and the tuck-in operation is performed,
while the weft is prevented from being disposed within the operation area of the needle
by stopping the injection of the air at the stoppage time of the loom caused by the
weft stoppage, thereby preventing the weft from being retained by the needle and tucked-in.
[0005] However, in the technique of the second prior art, although the weft end is not held
in the operation area of the needle by the injection of air at the time of weft stoppage,
the needle still swings, and hence the weft end contacted the needle is drawn into
and tacked in the shedding 34 of the warp when the needle retracts.
[0006] Accordingly, it is an object of the invention to easily draw out a defective weft
from a woven cloth in the case of the loom stoppage cause such as a weft stoppage
where the weft end is preferably not to be tucked in the shedding of the warp.
[0007] To achieve the above object, the invention assumes a tuck-in device 2 of a shuttleless
loom for folding back a weft end 37 of a weft 16 inside a shedding 34 of a warp 33
by injecting an air flow 32 after gripping the weft end 37 of the weft 16.
[0008] Particularly, a method of performing a tuck-in operation by the tuck-in device 2
of the shuttleless loom for folding back a weft end 37 inside a shedding 34 of a warp
33 allowing injection of the air flow 32 inoperative in response to an instruction
from a loom 1 based on a stoppage cause of the loom 1 not to fold back the weft end
37 inside the shedding 34 of the warp 33 or injecting the air flow 32 to fold back
the weft end 37 inside the shedding 34 of the warp 33 after the weft end 37 is gripped
and pulled by the first airflow 30, and injecting the first airflow 30 to pull and
grip the weft end 37, thereby preventing the weft end 37 from being folded back inside
the shedding 34 of the warp 33 during the injection of at least the air flow 32 in
response to the instruction from the loom 1 based on the stoppage cause of the loom
1.
[0009] The invention further provides a proper device for embodying the above method.
Fig. 1 is a plan view showing a state where a main part of a tuck-in device built
in a loom (shuttles loom) according to an embodiment of the invention;
Fig. 2 is a side view of the main part (block body) of the tuck-in device of the invention;
Fig. 3 is a block diagram of an airflow supply device of the tuck-in device of the
invention;
Fig. 4 is a timing diagram showing operations of constituent members of the tuck-in
device relative to a main shaft rotary angle of the loom at the time of normal tuck-in
operation;
Fig. 5 is a timing diagram showing operations of constituent members of the tuck-in
device relative to the main shaft rotary angle of the loom at the time of non tuck-in
operation;
Fig. 6(a) and Fig. 6 (b) are views explaining the main part (block body) of the tuck-in
device according to the embodiment of the invention at the time of non tuck-in operation,
wherein Fig. 6 (A) is a plan view and Fig. 6 (B) is a side view;
Fig. 7 is a timing diagram showing operations of constituent members of the tuck-in
device according to another embodiment of the invention relative to the main shaft
rotary angle of the loom at the time of non tuck-in operation; and
Fig. 8 is a view explaining the main part (block body) of the tuck-in device according
to another embodiment of the invention, wherein Fig. 8 (A) is a plan view and Fig.
8 (B) is a side view.
[0010] Figs. 1 and 2 show an embodiment where a tuck-in device 2 of the invention is built
in a loom (shuttleless loom) 1. The tuck-in device 2 is disposed at a weaving end
of a weft insertion or the weaving end of a weft arrival side. Further, a plurality
of cloths are woven, the tuck-in device 2 is also disposed between woven cloths. Fig.
1 shows the tuck-in device 2 disposed only at the weft arrival side. The tuck-in device
2 comprises a cutter 7 for cutting a weft 16, a block body 3 disposed between the
cutter 7 and a woven cloth end 31 of a woven cloth 5, and an airflow supply device
4 for supplying air to a gripping nozzle 12, a first tuck-in nozzle 18 and a second
tuck-in nozzle 19 integrally provided in the block body 3. Further, there is provided
an ejector 39, positioned opposite to the block body 3 while intervening the cutter
7, for drawing a cut end of the weft 16 which was cut by the cutter 7.
[0011] The block body 3 has a slit 9 which leaves open in three directions, namely, leaves
open at a front side thereof opposite to a reed 8, the cutter 7 side and the woven
cloth 5 side. Tapered guide surfaces 10 are positioned on an inner wall thereof at
the front entrance thereof and they are gradually enlarged in a slit width toward
the reed 8. The slit 9 has a gripping nozzle 12 on an upper wall 11 of its inner wall
and an airflow entrance port 14 on a lower wall 13 of its inner wall, and these gripping
nozzle 12 and airflow entrance port 14 penetrate the inner wall of the slit 9 from
upper and lower surfaces of the block body 3 and oppose each other. The gripping nozzle
12 is connected to the airflow supply device 4 through a gripping pipe 15 and receives
air from the airflow supply device 4 and injects it toward the airflow entrance port
14 when it operates. In this embodiment, although the gripping nozzle 12 is provided
on the upper wall 11 and the airflow entrance port 14 is provided on the lower wall
13, the airflow entrance port 14 may be provided on the upper wall 11 and the gripping
nozzle 12 may be provided on the lower wall 13.
[0012] Further, the slit 9 has the first tuck-in nozzle 18 on its innermost wall 17. Still
further, two second tuck-in nozzles 19 are provided up and down on the outer wall
of the block body 3 at the woven cloth end 31 side while intervening the slit 9 therebetween.
When viewing the two second tuck-in nozzles 19 from the reed 8 side, the two second
tuck-in nozzles 19 penetrate the block body 3 in a slanted manner while intervening
the slit 9 therebetween, and the central lines of nozzle holes of the second tuck-in
nozzles 19 cross each other in a shedding 34 of a warp 33 if they are extended.
[0013] One first tuck-in nozzle 18 and two second tuck-in nozzles 19 are structured to receive
air from the airflow supply device 4 through a first tuck-in pipe 26 and a second
tuck-in pipe 27.
[0014] Fig. 3 shows an injection control system of the tuck-in device 2. In Fig. 3, the
airflow supply device 4 comprises a pressure air source 20, pressure regulators 21
a, 21 b, closing valves 22, 23, 24 and a closing valve controller 25. The pressure
air source 20 is connected to the gripping nozzle 12 via the pressure regulator 21
a, the closing valve 22 and the gripping pipe 15. Air supplied from the pressure air
source 20 is branched at the pressure regulator 21 b. The pressure air source 20 is
connected to the first tuck-in nozzle 18 via the pressure regulator 21 b, the closing
valve 23 and the first tuck-in pipe 26, and also connected to the second tuck-in nozzle
19 via the pressure regulator 21 b, the closing valve 24, the second tuck-in pipe
27. The closing valve controller 25 opens and closes the closing valves 22, 23, 24
in response to a main shaft rotary angle signal of a loom issued by an encoder 29
connected to a main shaft 28 of the loom based on an injection timing set by a main
controller 35, and controls injection of air to be supplied to the gripping nozzle
12, the first tuck-in nozzle 18 and the second tuck-in nozzle 19.
[0015] The main controller 35 performs control necessary for stopping a tuck-in operation
in the manner of changing opening and closing control of the closing valves 22, 23,
24 upon reception of a weft stoppage signal from a weft detection sensor 36. The weft
detection sensor 36 is disposed on the side end of a reed holder 38 for detecting
the weft end 37 of the weft 16, and generating a weft stoppage signal at the time
of defective picking, and supplying this weft stoppage signal to the main controller
35.
[0016] When picking, the weft 16 is picked in the shedding 34 of the warp 33 and the weft
16 is beaten by the reed 8 and is beaten in a cloth fell 6 of the woven cloth 5. At
this time, the weft 16 enters the slit 9 and it is cut by the cutter 7 at its tip.
The cut weft end of the weft 16 is drawn by the ejector 39 and subjected to a discard
process. Thereafter, at the next picking time, the tuck-in device 2 sequentially injects
air through the gripping nozzle 12, the first tuck-in nozzle 18, and the second tuck-in
nozzles 19, whereby a tuck-in operation is performed by an airflow produced at this
time to fold back the weft end 37 of the weft 16 together with the airflow in the
shedding 34 formed at the next picking time.
[0017] Fig. 4 is a timing diagram showing an air injection timing of respective nozzles
relative to the main shaft rotary angle of the loom at the time of normal tuck-in
operation. At the time of normal tuck-in operation, the gripping nozzle 12 injects
air toward the airflow entrance port 14 for a given period of time to form a first
airflow 30 so that the weft end 37 of the weft 16 cut by the cutter 7 is pulled in
the airflow entrance port 14 inside the slit 9 and gripped at the locations of the
slit 9 and the airflow entrance port 14.
[0018] Then, the first tuck-in nozzle 18 injects air toward the reed 8 upon elapse of a
given period of time from the start of injection by the gripping nozzle 12 (formation
of the first airflow 30) to form an air flow 32a as a part of the air flow 32, while
the second tuck-in nozzle 19 injects air toward the shedding 34 of the warp 33 upon
elapse of a given period of time from the start of injection by the first tuck-in
nozzle 18 (formation of the air flow 32a) to form an air flow 32b as a part of the
air flow 32, thereby folding back the weft end 37 inside the shedding 34 of the warp
33. In such a manner, the tuck-in device 2 performs a tuck-in operation by folding
back the weft end 37 inside the shedding 34 of the warp 33.
[0019] The first airflow 30 is not only formed by the airflow injected from the gripping
nozzle 12 but also may be formed by an airflow drawn in the drawing pot of the airflow
entrance port 14 and by a plurality of different airflows.
[0020] The air flow 32 is formed by only the airflow injected from the injection port and
is not formed by the airflow drawn in the drawing port. The air flow 32 is preferable
to be formed by the plurality of airflows 32a, 32b which are differentiated in a direction
of injection as set forth above so as to expedite a tuck-in operation, but it may
be formed by a single airflow. Further, in this example, the plurality of airflows
may be combined with each other while injection timings thereof are differentiated
from each other.
[0021] Fig. 5 is a timing diagram showing air injection timings of respective nozzles relative
to the main shaft rotary angle of the loom at the time of non tuck-in operation caused
by the weft stoppage. When the weft 16 does not reach the weft detection sensor 36
due to defective picking, for example, due to short picking, the weft detection sensor
36 can not detect the weft 16 so that it outputs a weft stoppage signal to the main
controller 35 as a cause of the weft stoppage. The main controller 35 outputs a valve
opening inhibition signal of the closing valves 23, 24 to the closing valve controller
25 upon reception of the weft stoppage signal. At this time, although the closing
valve controller 25 allows the gripping nozzle 12 to inject air, it keeps the closing
valves 23, 24 in a closed state, and inhibits the first tuck-in nozzle 18 and the
second tuck-in nozzle 19 to inject air. Further, the injection by the gripping nozzle
12 may last longer than that during the normal period of time, for example, it may
continue or last, for example, until the completion of injection of air by the second
tuck-in nozzle 19 at the normal time. Meanwhile, the cutter 7 cuts the weft 16 inside
the slit 9 after beating in the same manner as the normal picking time.
[0022] Figs. 6(a) and 6(b) show the behavior of the weft 16 in the slit 9 of the block body
3 at the time of non tuck-in operation. The weft end 37 advanced inside the slit 9
by the beating of the reed 8 is cut by the cutter 7, then it is inserted in the airflow
entrance port 14 by the first airflow 30 from the gripping nozzle 12, and thereafter
pulled inside and gripped by the airflow entrance port 14. Thereafter, the main controller
35 stops the injection of air by the gripping nozzle 12.
[0023] In such a manner, the closing valve controller 25 breaks off the opening of the closing
valve 23 of the first tuck-in nozzle 18 and the closing valve 24 of the second tuck-in
nozzle 19 in response to the instruction from the loom 1 based on the weft stoppage
causing the stoppage of the loom 1, thereby not forming the air flow 32 (32a, 32b)
so that the weft end 37 stays in the airflow entrance port 14 and hence it is not
tucked in the shedding 34 of the warp 33. Meanwhile, ever if the first airflow 30
from the gripping nozzle 12 is stopped, the weft end 37 is held in the airflow entrance
port 14.
[0024] Although the non tuck-in operation is reliably performed by allowing both the airflows
32a, 32b inoperative in such a manner, either or both the airflows 32a, 32b may present
as weak airflows to the extent substantially not to perform the tuck-in operation
at the time of non tuck-in operation. Accordingly, "non-operation of the air flow
32 (32a, 32b)" has to be construed to include the presence of a weak airflow to the
extent substantially not to perform the tuck-in operation as well as the complete
non-operation. Further, in the case where the air flow 32 is formed of a plurality
of airflows like this example, when the injection of one of the airflows (e.g., 32b)
alone is inhibited as non-operation, the weft end 37 is not folded back in the shedding
34 by the other airflows (e.g., 32a) alone so that the entire air flow 32 is substantially
rendered inoperative. Accordingly, "non-operation of the air flow 32 (32a, 32b)" has
to be construed to include the case where the air flow 32 is formed of the plurality
of airflows, the case where all the airflows are rendered inoperative and the case
where only a part of the airflows is rendered inoperative.
[0025] Owing to the non tuck-in operation, after the loom 1 is stopped, an operator performs
pick finding of the cloth fell 6 by rotating the loom 1 in reverse, thereby extracting
a defective weft 16, which is not tucked in the shedding 34, from the cloth fell 6
of the woven cloth 5.
[0026] If a defective weft removing device is provided on a picking side, not shown, the
defective weft removing device receives an instruction from an operator or an instruction
from the loom 1, thereby taking the defective weft 16 therein to automatically remove
the defective weft 16 from the cloth fell 6 of the woven cloth 5. The defective weft
16 is displaced outside a cutting area by the airflow from an exclusive nozzle between
a picking nozzle, not shown, and the woven cloth 5 at the picking side, so as to facilitate
the extraction of the defective weft 16 or a cutter is rendered inoperative, and hence
the defective weft 16 remains to be connected to the weft 16 inside the picking nozzle.
[0027] Further, in this embodiment, the tuck-in device 2 performs the injection of the first
airflow 30 by the gripping nozzle 12, the injection of the air flow 32 (32a,32b) by
the first and second tuck-in nozzles 18 and 19 at a given timing as shown in Fig.
4 as made as usual, thereby performing the tuck-in operation in the case of the other
stoppage cause of the loom 1, for example, a warp stoppage and a manual stoppage of
the loom 1.
[0028] Fig. 7 is a timing diagram showing air injection timing of respective nozzles relative
to a main shaft rotary angle of a loom at the time of non tuck-in operation according
to another embodiment of the invention. A method of performing non tuck-in operation
of a shuttleless loom according to the embodiment in Fig. 7 is characterized in that
a weft end 37 in a slit 9 is not folded back inside a shedding 34 of a warp 33 by
injecting a first airflow 30 from a gripping nozzle 12 during the injection of at
least an air flow 32 (32a, 32b) by a first tuck-in nozzle 18 and a second tuck-in
nozzle 19 in response to an instruction from a loom 1 based on a stoppage cause of
a loom 1.
[0029] A main controller 35 outputs a valve opening continuation signal to a closing valve
controller 25 upon reception of a weft stoppage signal, and the closing valve controller
25 keeps the closing valve 22 in the opening state during a period of time longer
than a normal operation time, and injects the first airflow 30 from the gripping nozzle
12 during the injection of at least the air flow 32 (32a, 32b) by the first tuck-in
nozzle 18 and the second tuck-in nozzle 19. Meanwhile, the opening of the closing
valve 23 of the first tuck-in nozzle 18 and the opening of the closing valve 24 of
the second tuck-in nozzle 19 are respectively performed for a period of time in the
same manner as the normal tuck-in operation, thereby forming the air flow 32 (32a,
32b).
[0030] Fig .8 shows a behavior of a weft 16 at a slit 9 of a block body 3 at the time of
non tuck-in operation in the embodiment shown in Fig. 7. The weft end 37 which advanced
in the slit 9 by the beating of the reed 8 is cut by the cutter 7, then it is inserted
in an airflow entrance port 14 by the first airflow 30 from the gripping nozzle 12,
and thereafter pulled in and griped by the airflow entrance port 14. Since the injection
of the first airflow 30 from the gripping nozzle 12 continues until the completion
of the injection of the air flow 32 (32a, 32b) from the first tuck-in nozzle 18 and
the second tuck-in nozzle 19, the weft end 37 is pulled in and griped by the first
airflow 30 and stays in the airflow entrance port 14, and it is not tucked in the
shedding 34 of the warp 33 even if the air flow 32 (32a, 32b) is formed.
[0031] At this time, the injecting pressure of the first airflow 30 from the gripping nozzle
12 is increased compared with that at the normal time to prevent the weft end 37 from
being tucked in the shedding 34 of the warp 33 when the weft end 37 bows to the injection
pressure of the air flow 32 (32a, 32b), or the injection pressure of air flow 32 (32a,
32b) is decreased so that the weft end 37 is allowed to stay in the airflow entrance
port 14 with assurance to prevent the weft end 37 from being tucked in the shedding
34 of the warp 33. Further, if the injection period of the air flow 32 (32a, 32b)
is shortened, the continuous injection time of the first airflow 30 can be shortened,
thereby preventing an air pressure of a pressure air source 20 from being lowered
temporarily.
[0032] Since the closing valve controller 25 opens the closing valve 22 of the gripping
nozzle 12 during the opening of at lest the closing valves 23, 24 of the tuck-in nozzles
18, 19 in response to the instruction from the loom 1 based on the stoppage cause
of the loom 1 (weft stoppage), even if the air flow 32 (32a, 32b) is formed, the weft
end 37 stays in the airflow entrance port 14 and an operator rotates the loom 1 in
reverse to perform the pick finding, thereby extracting the defective weft 16, which
is not tucked in the shedding 34 of the warp 33, from the woven cloth 5 with ease.
[0033] In this embodiment, the operation to prevent the weft end 37 from being tucked in
the shedding 34 of the warp 33 by the injection of the air flow 32 (32a, 32b) by keeping
the gripping of the weft end 37 by the first airflow 30 is performed by taking over
the operation state of the first airflow 30 at the normal time so that the weft end
37 is prevented from being tucked in the shedding 34 of the warp 33 not owing to the
delay of the operation of a control system because the operation itself is not changed.
[0034] The operation to prevent the weft end 37 from being tucked in the shedding 34 of
the warp 33 by the injection of the air flow 32 (32a, 32b) while gripping the weft
end 37 by the first airflow 30 does not always continue from the operation to pull
in and grip the weft end 37 in the airflow entrance port 14. In the case where the
injection of the air flow 32 (32a, 32b) starts while delayed from the completion of
the first airflow 30 at the normal time or in the case where the injection of the
air flow 32 (32a, 32b) is temporarily interrupted, the operation to prevent the weft
end 37 from being tucked in the shedding 34 of the warp 33 may be interrupted in the
middle of the operation thereof. The manner of operation shown in Fig. 7 is a preferable
example for continuing the formation of the first airflow 30 until the completion
of the air flow 32 (32a, 32b). In this case, the operation to prevent the weft end
37 from being tucked in the shedding 34 of the warp 33 by the injection of the air
flow 32 while gripping the weft end 37 by the first airflow 30 is performed by taking
over the operation state of a normal airflow, and the closing valve 22 is not operated
in the middle of the operation, and hence there is an advantage that the weft end
37 is prevented from being tucked in the shedding 34 of the warp 33 not owing to the
delay of the operation.
[0035] According to the first aspect of the invention, in the case where the defective weft
is required to be extracted from the cloth fell of the woven cloth owing to the stoppage
cause of the loom such as the weft stoppage and the like, the airflow to fold back
the weft end is not injected in response to the instruction from the loom, so that
the weft end is not tucked in the shedding of the warp, thereby removing the defective
weft from the woven cloth with ease. Particularly, since (1) the operation per se
for folding back the weft end in the shedding of the warp is rendered inoperative,
there is no likelihood that the weft end is erroneously tucked in the shedding of
the warp, (2) since the injection of airflow is made after the gripping of the weft,
it is possible to cope with the instruction from the loom in good time, and (3) since
the non- operation of injection of the airflow is performed by continuing the inoperative
state of the injection, and the state of the injection is not changed during that
period of time, so that the weft end is not tucked in the shedding 34 of the warp
not owing to the delay of the changing operation, and hence the weft end is not reliably
tucked in the shedding of the warp.
[0036] According to the second aspect of the invention, when it is required to extract the
defective weft from the cloth fell of the woven cloth owing to the stoppage cause
of the loom such as the weft stoppage and the like, the state for gripping the weft
end by the first airflow is effected during the injection of at least airflow, so
that the weft end is not tucked in the shedding of the warp, thereby removing the
defective weft from the woven cloth with ease. Particularly, the gripping operation
for preventing the weft end from being tucked in the shedding of the warp by the injection
of the airflow among the weft end gripping operations by the first airflow is made
after the normal gripping operation by the first airflow, and hence it is possible
to cope with the instruction from the loom in good time, thereby reliably preventing
the weft end from being tucked in the shedding of the warp.
[0037] According to the apparatus of the third aspect of the invention, it can reasonably
realize the method of the first aspect of the invention, thereby obtaining the same
effect as the method of the first aspect of the invention.
[0038] According to the apparatus of the fourth aspect of the invention, it can reasonably
realize the method of the second aspect of the invention, thereby obtaining the same
effect as the method of the first aspect of the invention.
[0039] According to the fifth aspect of the invention, since the slit, the gripping nozzle,
the first tuck-in nozzle, and the second tuck-in nozzle are respectively disposed
in the block body in a reasonable state, a normal tuck-in operation is sequentially
effected by airflows, and also non tuck-in operation of the weft can be reliably executed
when the first tuck-in nozzle and the second tuck-in nozzle are not operated.
[0040] The features disclosed in the foregoing description, in the claims and/or in the
accompanying drawings may, both separately and in any combination thereof, be material
for realising the invention in diverse forms thereof.
1. A method of performing a tuck-in operation in a tuck-in device (2) of a shuttleless
loom for folding back a weft end (37) of a picked weft (16) inside a shedding (34)
of a warp (33) by injecting an air flow (32) after gripping the weft end (37) of the
picked weft (16), said method comprising:
allowing injection of the air flow (32) inoperative in response to an instruction
from a loom (1) based on a stoppage cause of the loom (1) not to fold back the weft
end (37) inside the shedding (34) of the warp (33).
2. A method of performing a tuck-in operation in a tuck-in device (2) of a shuttleless
loom for folding back a weft end (37) of a picked weft (16) inside a shedding (34)
of a warp (33) by injecting an air flow (32) after pulling and gripping the weft end
(37) of the picked weft (16) by a first airflow (30), said method comprising:
injecting the first airflow (30) during the injection of at least the air flow (32)
in response to an instruction from a loom (1) based on a stoppage cause of the loom
(1) not to fold back the weft end (37) to the shedding (34) of the warp (33).
3. A tuck-in device (2) of a shuttleless loom provided with one or more tuck-in nozzles
(18, 19) and an airflow supply device (4):
wherein the airflow supply device (4) comprises a pressure air source (20), closing
valves (23, 24) which open or close to permit or not permit the pressurized air in
the pressure air source (20) to be supplied or not supplied from the pressure air
source (20) to the tuck-in nozzles (18, 19), and a closing valve controller (25) for
controlling the closing valves (23, 24);
wherein a weft end (37) of a picked weft (16) is folded back inside a shedding
(34) of a warp (33) by injecting airflow from the tuck-in nozzles (18, 19) after the
weft end (37) of the picked weft (16) is gripped; and
wherein the closing valve controller 25 stops the opening of at least one of the
closing valves (23, 24) of the tuck-in nozzles (18, 19) in response to an instruction
from a loom (1) based on the stoppage cause of the loom (1).
4. A tuck-in device (2) of a shuttleless loom provided with a gripping nozzle (12), tuck-in
nozzles (18, 19) and an airflow supply device (4):
wherein the airflow supply device (4) comprises a pressure air source (20), closing
valves (22, 23, 24) which open or close to permit or not permit the pressurized air
in the pressure air source (20) to be supplied or not supplied from the pressure air
source (20) to the gripping nozzle (12) and the tuck-in nozzles (18, 19), and a closing
valve controller (25) for controlling the closing valves (22, 23, 24);
wherein a cut weft end (37) of a picked weft (16) is folded back inside a shedding
(34) of a warp (33) by injecting airflow from the tuck-in nozzles (18, 19) after the
cut weft end (37) of the picked weft (16) is pulled and gripped by air from the gripping
nozzle (12) or by air drawn in the gripping nozzle (12); and
wherein the closing valve controller (25) opens the closing valve (22) of the gripping
nozzle (12) during the opening of at least the closing valves (23, 24) of the tuck-in
nozzles (18, 19) in response to an instruction from a loom (1) based on the stoppage
cause of the loom (1).
5. A tuck-in device (2) of a shuttles loom provided with a block body (3) disposed close
to a woven cloth end (31) positioned in an outside of a woven cloth (5), and a airflow
supply device (4):
wherein the block body (3) has a slit (9) which leaves open in front thereof and
is opposite to a reed (8) for receiving a weft end (37) of a picked weft (16) during
a beating operation, and the slit (9) has a gripping nozzle (12) and an airflow entrance
port (14) provided opposite to each other on an upper wall (11) and a lower wall (13)
or vice verse, and a first tuck-in nozzle (18) provided on an innermost wall (17)
of the slit (9) and a second tuck-in nozzle (19) provided at the woven cloth end (31);
wherein the airflow supply device (4) comprises a pressure air source (20), closing
valves (22, 23, 24) which open or close to permit or not permit the pressurized air
in the pressure air source (20) to be supplied or not supplied from the pressure air
source (20) to a gripping nozzle (12), the first tuck-in nozzle (18) and the second
tuck-in nozzle (19), and a closing valve controller (25) for controlling the closing
valves (22, 23, 24);
wherein air is injected from the gripping nozzle (12) toward the airflow entrance
port (14) during a given period of time at the time of normal tuck-in operation to
form a first airflow (30), thereby pulling and holding the cut weft end (37), and
air is injected from the first tuck-in nozzle (18) toward the reed (8) during a given
period of time after the start of injection from the gripping nozzle (12), and air
is injected from the second tuck-in nozzle (19) toward the shedding (34) of the warp
(33) during a given period of time after the start of injection from the first tuck-in
nozzle (18), thereby folding back the weft end (37) inside the shedding (34) of the
warp (33); and
wherein the closing valve controller (25) stops to open at lest one of the closing
valves (23, 24) of the first and second tuck-in nozzles (18, 19) in response to an
instruction from a loom (1) based on a stoppage cause of the loom (1).