TECHNICAL FIELD OF THE INVENTION
[0001] The present invention concerns a heddle module for a drawing-in machine. The present
invention also concerns a drawing-in machine for drawing-in warp threads into heddles
of a loom, said drawing-in machine including, amongst others, a heddle module. Finally,
the present invention concerns a method for feeding heddles to a heddles-transport
device of a heddle module.
[0002] The present invention belongs to the technical field of drawing-in warp threads into
heddles of a loom.
BACKGROUNG OF THE INVENTION
[0003] Duplex heddles are sometimes used for heddle frames in order to allow higher densities
of warp yarns. Duplex heddles comprise left and right heddles, which include a central
eyelet and two upper and lower end loops. Left and right heddles differ by their geometries,
mostly in their intermediate region, around their eyelet. For high warp yarn densities,
the heddles shall be provided with a regular alternation of left and right heddles
on each heddle frame.
[0004] Current drawing-in machines can be equipped with two heddles-feeding device, namely
a right heddles-feeding device and a left heddles-feeding device. Each heddles-feeding
device includes a stack of right heddles and a stack of left heddles and, according
to a heddle sequence, one heddle can be separated from one of the two stacks at a
time, e.g. by using a heddles-separating device known from
WO00/1 1252A1 or
WO99/15723A1.
[0005] Each separated heddle is fed to a transport device, which moves the heddles to a
threading position, where a yarn is inserted into the eyelet of each heddle by a threading
device, then to one of several discharge positions on respective rods of a heddles-receiving
module.
[0006] This operation relies on the fact that left and right heddles are separated and identified
prior to being loaded on the transport device. When stacks of duplex heddles are removed
from a heddle frame to be re-used for a next drawing-in process, the alternation between
left and right heddles might not be fully respected. Thus, an operator shall separate
duplex heddles in a stack of left heddles and a stack of right heddles before installing
the two different stacks on two feeding devices, for feeding the heddles-separating
device.
[0007] This is time-consuming for the operator and can be source of errors.
SUMMARY OF INVENTION
[0008] The purpose of the prevent invention is to avoid this step of separating the heddles
into a stack of left heddles and another stack of right heddles before using the heddles
on the drawing-in machine. The purpose of the invention is also to speed up the feeding
of heddles to a transport device.
[0009] To this end, the invention concerns a heddle module for a drawing-in machine, said
heddle module comprising a heddles-feeding device where heddles are provided in the
form of at least one stack, a heddles-separating device configured to separate one
heddle from the at least one stack, a heddles-transport device, configured to move
heddles according to a predetermined heddle sequence corresponding to a succession
of heddle types among left heddle and right heddle, from at least one transport transfer
position to a threading position, where a thread is inserted into the transported
heddle. According to the invention, the heddle module also comprises a heddles-sorting
device including at least one sorting conveyor equipped with several heddle-support
elements adjacent to each other along a sorting path, each heddle-support element
being configured to hold one separated heddle and to move the separated heddle from
at least one feeding position to at least one sorting transfer position along the
sorting path. The heddle module also comprises a heddles-transfer device, for transferring
a separated heddle out of at least one heddle-support element located at the at least
one sorting transfer position onto the heddles-transport device at the at least one
transport transfer position, and a heddles-detection device configured to detect at
least one parameter of a heddle, before the heddle is transferred by the heddles-transfer
device, the parameter being different depending on whether the heddle is a left heddle
or a right heddle . The heddle module also comprises a controller connected at least
to the heddles-detection device and to the heddles-sorting device and configured to
determine the heddle type from the parameter detected for a heddle by the heddles-detection
device and to command the heddles-sorting device to move a heddle carried by the sorting
conveyor to the sorting transfer position according to the heddle type for this heddle
and according to the predetermined heddle sequence. The heddles-separating device
is interposed between the heddles-feeding device and the sorting conveyor and configured
to bring the separated heddle into engagement with at least one heddle-support element
in the at least one feeding position.
[0010] Thanks to the invention, the heddles-sorting device allows feeding the heddles-transport
device according to a predetermined heddle sequence, thus respecting the distribution
of left and right heddles, from the stack of heddles where the heddles can be right
and left heddles in any order. In other words, the heddles-sorting device, the heddles-transfer
device, the heddles-detection device and the controller allow the heddle module of
the invention to correctly position and alternate the left and right heddles in a
drawing-in machine according to a drawing-in draft, without having an operator to
sort the heddles into two different stacks of left heddles and right heddles.
[0011] For the present invention, a drawing-in draft corresponds to how successive warp
threads are to be drawn through the heddles of heddle frames of a loom, in order to
produce a fabric with a desired pattern on the loom. A drawing-in draft is, for instance,
prepared for all fancy patterns woven on a loom. It can include how warp threads are
to be drawn through the dropwires of a loom. The warp threads can come from a warp
beam or from a bobbin.
[0012] For the present invention, a heddle sequence is a succession of heddle types among
left heddle and right heddle. This heddle sequence can be a regular or irregular alternance
of left and right heddles. The heddle sequence can be determined from a drawing-in
draft or can be a preset heddle sequence.
[0013] Duplex heddles are heddles for heddle frames and can have any type of end loop and
of eyelet.
[0014] According to advantageous but non-compulsory aspects of the invention, such a heddle
module might incorporate one or several of the following features:
- The sorting path is a closed sorting path, whereas the heddle-support elements that
are adjacent to each other along the closed sorting path are regularly distributed
along the closed sorting path and whereas, when a first heddle-support element is
at the feeding position, a second heddle-support element is at the sorting transfer
position and at least one heddle-support element is located between the first and
second heddle-support elements, on both sides of the first heddle-support element
along the closed sorting path.
- Each sorting conveyor includes at least one endless member movably arranged around
a frame of the heddles-sorting device and on which the several adjacent heddle-support
elements are secured, and at least one drive of the sorting conveyor drives a driving
wheel in engagement with the endless member for moving the heddle-support elements
of the respective endless member along the sorting path.
- When it is arranged around the frame of the heddles-sorting device, the endless member
has an elongated shape with two opposite long straight sides and with its longest
dimension perpendicular to a longitudinal axis of the heddles-feeding device and the
at least one feeding position and the at least one sorting transfer position are respectively
arranged on the two opposite long straight sides of the endless member.
- The endless member is a belt and each heddle-support element includes a recess where
an external protrusion of the belt is received and is secured to the belt by a screw
screwed in the external protrusion.
- Each heddle-support element has upper and lower guiding members configured to cooperate
with guiding rails of the frame of the heddles-sorting device, the rails extending
parallel to at least a portion of the sorting path.
- The controller includes a memory for storing value of the parameter detected by the
heddle-detection device or a heddle type information derived from this parameter for
each heddle carried by the sorting conveyor in relation to the at least one heddle-support
element supporting this heddle.
- The heddles-transfer device includes at least one motorized pusher housed in the frame
of the heddles-sorting device and configured to push a heddle out of the at least
one heddle-support element located at the at least one sorting transfer position into
the at least one transport transfer position.
- The heddles-detection device includes a camera oriented to aim at a zone around an
eyelet of the heddle when the heddle is in a detection position.
- Each heddle-support element is equipped with a first nail; the heddles-transport device
includes at least one transport conveyor equipped with several heddle-holding elements
spaced along a transport path; each heddle-holding element is equipped with a second
nail and a first nail of a heddle-support element located at the sorting transfer
position and a second nail of a heddle-holding element located at the transport transfer
position are aligned along a direction parallel to the longitudinal axis of a heddle,
the first nail and the second nail being adapted to penetrate into the same end loop
of the heddle when the heddle is transferred by the heddles-transfer device from the
sorting transfer position to the transport transfer position.
- The sorting conveyor includes an upper sorting conveyor portion and a lower sorting
conveyor portion; the upper sorting conveyor portion is arranged on an upper frame
of the heddles-sorting device and equipped with several heddle-support elements, each
adapted to interact with an upper end loop of a heddle; the lower sorting conveyor
portion is arranged on a lower frame of the heddles-sorting device and equipped with
several heddle-support members, each adapted to interact with a lower end loop of
a heddle; a heddle-support element of the upper sorting conveyor portion and a heddle-support
element of the lower sorting conveyor portion form a pair of heddle-support elements
cooperating with the same heddle; the heddles-sorting device comprises several pairs
of heddle-support elements that are spaced and movable along the sorting path and
an upper drive of the upper sorting conveyor portion and a lower drive of the lower
sorting conveyor portion are synchronized by the controller.
[0015] According to a second aspect, the invention concerns a drawing-in machine for drawing-in
warp threads into harness components for a loom. This drawing-in machine comprises
a heddle module as mentioned here above, a thread-insertion device for inserting a
warp thread through a heddle located at the threading position and a heddles-receiving
module comprising several adjacent heddle-support rods. The heddles-transport device
of the heddle module is configured to move heddles according to the predetermined
heddle sequence from the at least one transport transfer position to one of several
discharge positions, where each transported heddle can be transferred out of the heddles-transport
device onto the heddles-receiving module, each heddle-support rod facing one of several
discharge positions. The number of heddle-support elements that can hold different
heddles on the heddles-sorting device is strictly larger than the number of discharge
positions.
[0016] According to a third aspect, the invention concerns a method for feeding heddles
to a heddles-transport device of a heddle module of a drawing-in machine, according
to a heddle sequence corresponding to a succession of heddle types among left and
right heddles and prior to inserting a thread in this heddle. Said method is implemented
with a heddles-sorting device equipped with several heddle-support elements spaced
along a sorting path of the heddles-sorting device and co-moved along the sorting
path and with a heddles-feeding device in which heddles are provided in the form of
at least one stack of left and right heddles. Each heddle-support element is configured
to hold one heddle. The heddles-sorting device is configured to move several heddles
at the same time along the sorting path; both left and right heddles can be transferred
between the sorting transfer position and the transport transfer position. The method
includes at least the following steps consisting in:
- a) moving the heddle-support elements of the sorting device along the sorting path
up to placing a free heddle-support element at a feeding position;
- b) separating a heddle from the at least one stack;
- c) detecting a parameter representative of the geometry of the heddle, the parameter
differing depending on whether the heddle is a left heddle or a right heddle;
- d) feeding the free heddle-support element located at the feeding position with a
heddle, at the feeding position;
- e) moving the heddle-support elements of the heddles-sorting device along the sorting
path in order to place, in the sorting transfer position, a heddle-support element
holding a heddle whose detected parameter corresponds to a predetermined value, the
predetermined value depending on the heddle sequence; and
- f) moving the heddle out of the heddle-support element located at the sorting transfer
position onto a heddle-holding element of the heddles-transport device located at
a transport transfer position.
[0017] Advantageously, the method includes at least the following steps consisting in
g) memorizing for each heddle-support element of the heddles-sorting device if a heddle
is held or if the heddle-support element is free; and
h) if a heddle is held by a heddle-support element, memorizing, for this heddle-support
element, the parameter detected at step c) for this heddle or another parameter representative
of the left or right type of this heddle.
[0018] According to optional features, the sorting path is a closed sorting path and/or,
during steps a) and e), a movement of the heddle-support elements is possible in both
directions along the closed sorting path.
BRIEF DESCRIPTION OF THE DRAWINGS
[0019] The invention will be better understood, based on the following description, which
is given in correspondence with the appended figures and as an illustrative example,
without restricting the object of the invention. In the annexed figures:
- Figure 1 is a partial top view of a drawing-in machine according to the invention,
this machine incorporating a heddle module according to the invention;
- Figure 2 is a partial isometric view of the drawing-in machine of the invention;
- Figure 3 is a partial front view of the drawing-in machine of the invention, it shows
the plane I-I along which figure 1 is taken ;
- Figure 4 is an enlarged view of detail IV on figure 1 ;
- Figure 5 is a partial enlarged sectional view along line V-V on figure 4, at the level
of an upper conveyor section ;
- Figure 6 is an isometric detail view of the drawing-in machine at two transfer positions;
- Figure 7 is an isometric detail view of the drawing-in machine, with a heddle at a
detection position;
- Figure 8 is a perspective view of an endless belt used in a transport device of the
drawing-in machine of the invention;
- Figure 9 is a partial enlarged sectional view along line IX-IX on figure 1;
- Figure 10 is a partial enlarged sectional view along line X-X on figure 1;
- Figure 11 is a partial top view, similar to figure 1, for a heddle module and a drawing-in
machine according to a second embodiment of the invention; and
- Figure 12 is a partial front view of the drawing-in machine of figure 11.
DETAILLED DESCRIPTION OF SOME EMBODIMENTS
[0020] The drawing-in machine 2 schematically represented on figure 1 comprises a heddles-feeding
device 4, which includes a stack 6 of duplex heddles 60. The duplex heddles can be
of two types, namely left heddles 60L or right heddles 60R.
[0021] A heddle is an example of a harness component usable on a loom.
[0022] The drawing-in machine 2 also includes a heddles-separating device 8, a heddles-sorting
device 10, a heddles-transport device 12, a heddles-detection device 14, a controller
16, a thread-insertion device 18, a heddles-receiving module 20, a dropwire module
22, a warp-clamping frame 24 for clamping warp yarns of a non-represented warp beam,
a heddles-transfer device 26 and a heddles-discharging device 28.
[0023] The thread-insertion device 18 may be common to heddles and dropwires.
[0024] The heddles-feeding device 4, the heddles-separating device 8, the heddles-sorting
device 10, the heddles-transport device 12, the heddles-detection device 14, the controller
16 and the heddles-transfer device 26 belong to a heddle module 30, which is part
of the drawing-in machine 2.
[0025] X, Y, Z denote an orthogonal marker of a non-represented frame of the drawing-in
machine 2 with reference axes X and Y horizontal and reference axis Z vertical and
oriented to the top.
[0026] The heddles-feeding device 4 comprises a single magazine made of two guide rails
42, vertically aligned, which support a single stack 6 of duplex heddles 60. The heddles
60 are supported by their respective end loops 62 and the rails 42 are fixed with
regard to a non-represented frame of the drawing-in machine 2. The rails 42 can be
inclined relative to a horizontal plane, as considered in
WO00/68479A1, or parallel to such a horizontal plane, as considered in
WO99/15723A1. In the example of the figures, the guide rails 42 extend parallel to the reference
axis Y. In other words, the reference axis Y is a longitudinal axis of the heddles-feeding
device 4 and, within the stack 6, the heddles 60 are adjacent to each other along
the longitudinal axis Y.
[0027] A60 denotes a longitudinal axis of a heddle 60. This axis A60 extends between the
end loops 62 of each heddle 60 and is parallel to their longest dimension. This longitudinal
axis A60 is parallel to the reference axis Z when the corresponding heddle is mounted
on the heddles-feeding device 4, on the heddles-sorting device 10 and on the heddles-transport
device 12.
[0028] In the stack 6, heddles 60 can be of two types, namely left heddle 60L or right heddle
60R. Left heddle 60L and right heddle 60R differ at least in the position, in a direction
perpendicular to axis A60, of their intermediate region and of their eyelet 64, with
regard to the end loops 62.
[0029] In practice, the heddle stack 6 can be directly extracted from a heddle frame that
has been previously used on a loom. Such a stack 6 includes right and left heddles
60L, 60R but their alternation might be altered by heddles added on the frame during
its previous period of use on a loom. Thanks to the heddles-sorting device the distribution
of heddles 60 in the stack 6 does not have to be precisely known nor controlled in
advance
[0030] The heddles-separating device 8 is configured to separate heddle 60 one by one from
the stack 6 of heddles 60 borne by the magazine formed by the two guide rails 42 and
to transfer each separated heddle one after the other onto the heddles-sorting device
10 at a feeding position P1. On the figures, the heddles-separating device 8 is partially
shown. The heddles-separating device 8 can be built as disclosed in
WO00/68479A1 or
WO99/15723A1 whose contents are included in this description by reference. Alternatively, other
types of heddles-separating devices can be used in the heddle module 30.
[0031] The sorting device 10 comprises a sorting conveyor 100 made of an upper sorting conveyor
portion 102 and a lower sorting conveyor portion 104 which extend parallel to each
other, one above the other.
[0032] Each sorting conveyor portion 102 or 104 includes an endless belt 108, which forms
an endless member defining a closed sorting path 106 when it is mounted on a frame
120 of the sorting device 10.
[0033] Each endless belt 108 is equipped with several heddle-support elements 122. By convention,
a heddle-support element 122 secured to the endless belt 108 of the upper sorting
conveyor portion 102 is an upper heddle-support element and a heddle-support element
122 secured to the endless belt 108 of the lower sorting conveyor portion 102 is a
lower heddle-support element. An upper heddle-support element 122 interacts with an
upper end loop 62 of a heddle 60 mounted on the sorting device 10, whereas a lower
heddle-support element 122 interacts with the lower end loop 62 of the same heddle
60. On each endless belt 108, the heddle-support elements 122 are adjacent to each
other along the sorting path 106. In other words, each heddle-support element 122
of each endless belt 108 is shifted along the sorting path 106 with regard to the
other heddle-support elements 122 of the same endless belt 108. Each heddle-support
element 122 is configured to hold one heddle 60 and the heddle-support elements 122
co-move with the endless belt 108 along the sorting path 106. Alternatively, a steel
band or a chain can be used as an endless member, instead of a polymer belt. The endless
member can take different shapes when not mounted on the frame.
[0034] The closed sorting path 106 has an elongated or oblong shape with its longest dimension
parallel to the reference axis X and perpendicular to the main direction of the guide
rails 42. Each endless belt 108 has an elongated or oblong shape that corresponds
to the shape of the closed sorting path 106.
[0035] Two servomotors 112, 114 are respectively engaged with gears 116 and drive toothed
wheels 118 in meshing engagement with the inner surface of each belt 108. Advantageously,
the inner surface of each belt 108 is provided with teeth 109, in order to cooperate
with teeth provided on the radial external surface of the respective wheels 118. Each
wheel 118 rotates around a rotation axis X118, which is parallel to the reference
axis Z.
[0036] The two servomotors 112 and 114 form drives for the sorting conveyor 100, more precisely
for the respective endless belts 108 of its upper and lower sorting conveyor portions
102 and 104. The servomotor 112 forms an upper drive for the upper conveyor portion
102 and the servomotor 114 forms a lower drive for the lower conveyor portion 104.
[0037] As shown by double arrow A1, the two servomotors 112 and 114 can drive the endless
belts 108, and thus the heddle-support element 122, in two opposite directions along
the closed sorting path 106.
[0038] The upper and lower servomotors 112 and 114 are electrically synchronized by the
controller 16, preferably with no direct mechanical link between them. Preferably
upper and lower sorting conveyor portions 102 and 104 follow the same movement when
they are driven by upper and lower servomotors 112 and 114.
[0039] The heddles-sorting device 10 includes the frame 120, which supports the two sorting
conveyor portions 102 and 104, in particular the servomotors 112 and 114, the gears
116 and the wheels 118. The endless belts 108 are arranged around this frame 120 and
the closed sorting path 106 is defined around this frame.
[0040] As visible on figures 2 and 3, the two servomotors 112 and 114 can be respectively
located above and under the upper and lower conveyor portions 102 and 104. It should
be noted here that figure 1 is a top view of the drawing-in machine 2, seen from a
middle plane I-I, located between the upper conveyor portion 102 and the lower conveyor
portion 104, as shown on figure 3.
[0041] The frame 120 is rigidly secured to the non-represented frame of the drawing-in machine
2.
[0042] Advantageously, the upper and lower heddle-support elements 122 are identical, except
for their orientation along the reference axis Z.
[0043] The heddles-receiving module 20 includes twenty pairs of support rods 202 arranged
parallel to each other and adjacent to each other along a direction parallel to the
reference axis X, on a side of the heddles-transport device 12 opposite to the heddles-sorting
device 10. These twenty pairs of support rods 202 correspond to twenty discharge positions
of the heddles-transport device 12. These pairs of support rods are individually referenced
202
k, with k an integer between 1 and 20.
[0044] Advantageously, the number of heddle-support elements 122 mounted on each endless
belt 108 is strictly larger than the number of discharge positions of the heddles-transport
device, i.e. the number of pairs of support rods 202 that can be installed in the
receiving module 20 of the drawing-in machine 2. In other words, the number of heddle-support
elements 122 of the sorting conveyor 100 that can hold different heddles, which is
the maximal heddle capacity of the sorting conveyor 100, is strictly larger than the
number of discharge positions. In the present example, since there are twenty pairs
of support rods 202
1 to 202
20, the number of heddle-support elements 122 on each endless belt 108 is larger than
or equal to twenty-one, in practice equal to twenty-four as shown, for example, on
figure 4.
[0045] Alternatively, a different number of heddle-support elements 122 can be secured to
each endless belt 108, this number being strictly larger than the number of discharge
positions. Advantageously, the number of heddle-support elements 122 mounted on each
endless belt 108 is at least five.
[0046] The heddle-support elements 122 are regularly distributed on the external peripheral
surface 108A of each endless belt 108. The two endless belts, that is the endless
belt 108 of the upper conveyor portion 102 and the endless belt 108 of the lower conveyor
portion 104, are equipped with the same number of heddle-support elements 122. The
upper heddle-support elements 122 and the lower heddle-support elements 122 form pairs
of heddle-support elements 122. More precisely, two vertically aligned support elements
122, i.e. two heddle-support elements aligned to hold a heddle 60 with its axis A60
parallel to the reference axis Z, form a pair of heddle-support elements configured
for holding a heddle 60.
[0047] Each heddle-support elements 122 is secured to the external peripheral surface 108A
of one of the belts 108 by a screw 124. This is visible in particular on figure 5,
which is a partial cut view taken along a plane radial to the rotation axis X118 of
a wheel 118, at the level of the upper conveyor section 102. On figure 4, the line
V-V shows the trace of this plane at the level of the lower conveyor section 104.
[0048] Each heddle-support element 122 includes a polymer body 126 fixed to the endless
belt 108 by the screw 124 and provided with two guiding parts 128 and 130 that can
cooperate with two guiding rails 120A and 120B which belong to the frame 120. The
two guiding parts 128 and 130 can be respectively engaged within two guiding slots
132 and 134 formed by the two guiding rails 120A and 120B.
[0049] Alternatively, the body 126 of a heddle-support element 122 can be made of another
material, e.g. metal.
[0050] The longest dimension of the closed sorting paths 106 is parallel to the reference
axis X and the guiding rails 120A and 120B are parallel to this axis.
[0051] Advantageously, the two rails 120A and 120B, thus the two guiding slots 132 and 134,
extend parallel to straight portions of the closed sorting path 106, in particular
to two long straight sides of the belt 108 .
[0052] For the sake of clarity, only one rail 120A is represented on figure 2, the other
one being omitted in order to show the upper guiding parts 128 of some heddle-support
elements 122.
[0053] Advantageously, the external peripheral surface 108A of the endless belts 108 include
regularly distributed external protrusions, each equipped with a threaded hole 108B
adapted to receive one screw 124 and each body 126 has a recess 126A configured to
receive one such external protrusion. In practice, the number of protrusions provided
on the external surface 108A of each endless sorting belt 108 equals the number of
heddle-support elements 122 mounted on this endless belt.
[0054] Each body 126 is provided with three superimposed bores 126B adjacent to one another
along the reference axis Z. Only the intermediate bore 126B accommodates a screw 124
when the corresponding heddle-support element 122 is secured to an endless belt 108.
[0055] Each heddle-support element 122 also includes a pin 136, mounted on the body 126
and equipped with a nail 138 configured for penetrating in an end loop 62 of a heddle
60. The pin 136 of a heddle-support element 122 is slidable, with respect to the body
of this heddle-support element 122, along an axis, which is vertical when the heddle-support
element 122 is mounted in the heddles-sorting device 10.
[0056] Each pin 136 of an upper heddle-support element 122 is loaded upwardly, with respect
to its body 126, by a spring 140. Conversely, each pin 136 of a lower heddle-support
element 122 is loaded downwardly, with respect to its body 126, by a spring 140. Thus,
the pins 136 of the heddle-support elements 122 of one of the upper and lower conveyor
portions 102 and 104 are loaded by the springs 140 in a direction away from the other
conveyor portion 104 or 102. As a result, the pins 136 of the two heddle-support elements
122 of a pair of heddle-support elements are loaded by their respective springs 140
in opposite directions, away from each other.
[0057] The heddles-sorting device 10 also defines a sorting transfer position P2. When a
heddle is in this sorting transfer position P2, it can be moved by the heddles-transfer
device 26 into a transport transfer position P3 defined by the heddles-transport device
12.
[0058] The heddles-transfer device 26 includes a pusher 262 housed in the frame 120 of the
heddles-sorting device 10 and movable relative to this frame 120 and to the conveyor
portions 102 and 104 in a direction parallel to the reference axis Y, between a retracted
position represented on figures 1 and 4 and in solid lines on figure 6, on the one
hand, and an extended position represented in dotted lines on figure 6, on the other
hand. The heddles-transfer device 26 also includes a non-represented drive configured
to move the pusher 262 between its retracted and extended positions, and vice-versa.
[0059] In the retracted position of the pusher 262, a heddle 60 is in the sorting transfer
position P2, whereas the same heddle has been moved into the transport transfer position
P3 when the pusher 262 is in its extended position.
[0060] In practice, the heddles-transfer device 26 can incorporate two pushers 262, one
next to each conveyor portions 102 and 104. An upper pusher 262 can be located just
below the pin 136 of the upper heddle-support elements 122 and a lower pusher 262
can be located just above the pin 136 of the lower heddle-support elements 122.
[0061] In its retracted position, each pusher 262 does not interfere with the heddles 60
borne by the heddles-sorting device 10 and moving along the closed sorting path 106.
In its extended position, each pusher 262 crosses the closed sorting path 106 and
pushes the heddle 60 hold by the adjacent pair of heddle-support elements 122 out
of the sorting transfer position P2 and towards the transport transfer position P3.
[0062] The feeding position P1 and the sorting transfer position P2 are regularly spaced
along the closed sorting path 106. In other words, the distance between the feeding
position P1 and the sorting transfer position P2 is the same in both directions A1
along the sorting path 106.
[0063] The heddle-support elements 122, that are adjacent to each other along the closed
sorting path 106, are regularly distributed along the closed sorting path 106, in
a way which takes into count the repartition of the two positions P1 and P2. More
precisely, when a first heddle-support element 122 is at the feeding position P1,
a second heddle-support element 122 is at the sorting transfer position P2, and at
least one heddle-support element 122 is located between the first and second heddle-support
elements, on both sides of the heddle-support element 122 along the closed sorting
path 106.
[0064] Advantageously, and as shown on the figures, the two positions P1 and P2 are located
on opposite long straight sides of the oblong sorting belt 108 and the distance between
the feeding position P1 and the sorting transfer position P2 along the closed sorting
path 106 is the same in both directions.
[0065] Preferably, the number of heddle-support elements 122 between the two positions P1
and P2 and along the closed sorting path 106 is the same in both directions.
[0066] In the example of the figures, this number is 10. In a variant, this number can be
different. It is preferably chosen larger than or equal to 1.
[0067] Release means 162 are provided at the feeding position P1. When actuated by a dedicated
non-represented drive, these release means 162 push the pins 136 of the two heddle-support
elements 122 of a pair of heddle-support elements present at the feeding position
P1 towards each other, against the action of their respective return springs 140,
in two opposite directions parallel to the reference axis Z. In other words, the pin
136 of one upper heddle-support element 122 is pushed downwardly, whereas the pin
136 of the lower heddle-support element 122 of the same pair is pushed upwardly by
the release means 162.
[0068] This results in moving the nails 138 of these two heddle-support elements 122 towards
each other, which allows each of these nails to engage within a respective end loop
62 of the separated heddle presented by the heddles-separating device 8.
[0069] When the release means 162 are no more actuated or when the heddle-support elements
122 of the pair of heddle-support elements leave the feeding position P1, the pins
136 of the two heddle-support elements of the pair of heddle-support elements 122
present in the feeding position P1 are pushed back by their respective springs 140
into their return positions, which hooks the two nails 138 of the two heddle-support
elements 122 present in the feeding position P1 within the two end loops 62 of the
heddle 60. This results in tensioning the heddle 60 between the nails 138 of the pair
of heddle-support elements.
[0070] As visible on figure 5, the nail 138 of each heddle-support element 122 is not parallel
to the horizontal plane defined by axes X and Y but inclined with respect to this
plane by a non-zero angle α.
[0071] The nail 138 of an upper heddle-support element 122 diverges upwardly, by an angle
α, when going away from the corresponding pin 136, whereas the nail 138 of a heddle-support
element 122 of the lower conveyor portion 104 diverges downwardly, by the same angle
α, when going away from the corresponding pin 136. Thus, the two nails 138 diverge.
[0072] Advantageously, the angle α is between 0 and 8°, preferably equal to 5°.
[0073] Due to the divergence of the two nails 138, the elastic force exerted by the two
springs 140 of a pair of heddle-support elements 122 contributes to hooking a heddle
60 between these two elements. This contributes to keeping a heddle 60 stable on a
pair of heddle-support elements 122 when it is moved along the closed sorting path
106 by the sorting conveyor 100.
[0074] Two non-represented sensors are integrated within the sorting device 10 and provide
the controller 16 with an information about the position of each endless belt 108
of the upper and lower sorting conveyor portions 102 and 104 relative to the frame
120. This allows the controller 16 to know, at any time, the position of each heddle-support
element 122 along the closed sorting path 106.
[0075] The heddles-detection device 14 is configured to detect if a heddle 60 is a left
heddle 60L or a right heddle 60R.
[0076] A detection position P4 is defined between the stack 6 of heddles 60 and the feeding
position P1.
[0077] Preferably, the heddles-detection device 14 includes a camera 142 mounted on the
frame of the drawing-in machine so that its field of view 144 covers a zone around
the eyelet of a right heddle 60R located in the detection position P4 and a zone around
the eyelet of a left heddle 60L located in the detection position P4.
[0078] The region of a heddle 60 around its eyelet 64 allows differentiating a left heddle
60L from a right heddle 60R. Thus, the camera 142 is configured to detect at least
one parameter of a heddle 60 present in the detection position P4, this parameter
being different, depending on whether the heddle is a left heddle 60L or a right heddle
60R. This parameter can be given by the geometry of the heddle around its eyelet.
[0079] In practice, the heddles-detection device 14 sends to the controller 16 a signal
S14 including the at least one parameter of the heddle, which allows differentiating
a left heddle 60L from a right heddle 60R.
[0080] Advantageously, the signal S14 also includes an information as to whether the heddle
eyelet 64 is correctly oriented, if it is worn, how much it is worn and at which position
the eyelet 64 is located relative to the upper and lower heddle loops 62 of the heddle,
depending on some wear within the end loops 62. All this information can be derived
from a picture taken by the camera 142 and included within the signal S14 sent to
the controller 16.
[0081] Preferably, the detection position P4 is located on the path of a heddle 60 after
this heddle has been separated from the stack 6 and before this heddle is transferred
onto the heddles-sorting device 10.
[0082] Advantageously, the controller 16 sends a signal to the heddles-detection device
14 in order to take a picture of each separated heddle 60 as soon as it is separated
from the stack 6 but still held by the heddles-separating device 8.
[0083] Advantageously, the heddles-detection device 14 can also be used as a separation
detection device in order to detect "double heddle separation", i.e. when two heddles
are separated from the stack 6 at the same time.
[0084] The heddles-transport device 12 is exclusively dedicated to transporting heddles
and includes several transport conveyors.
[0085] In the first embodiment, the heddles-transport device 12 includes three transport
conveyors 300A, 300B and 300C. In a variant, the number of transport conveyors can
be different, but larger than or equal to two.
[0086] The three conveyors 300A, 300B and 300C are superimposed. More precisely, a first
upper conveyor 300A is located above a second intermediate conveyor 300B, which is
located above a third lower conveyor 300C along the reference axis Z.
[0087] The first transport conveyor 300A includes an upper conveyor portion 302A and a lower
conveyor portion 304A. The second transport conveyor 300B includes an upper conveyor
portion 302B and a lower conveyor portion 304B. The third transport conveyor 300C
includes an upper conveyor portion 302C and the lower conveyor portion 304C.
[0088] Several heddle-holding elements 322 are secured to, thus co-moved with, each transport
conveyor 300A, 300B, 300C along a closed transport path 306 which is common to all
transport conveyors 300A, 300B, 300C. Each heddle-holding elements 322 is configured
to hold a single harness component, which is, in this first embodiment, a single heddle
60. The harness component-holding elements 322 of the three transport conveyors 300A,
300B and 300C are adjacent to each other along the closed transport path 306. In other
words, the harness component-holding elements 322 of each of the transport conveyors
300A, 300B and 300C are shifted along the transport path 306 with regard to the harness
component-holding elements 322 of the other transport conveyors 300A, 300B and 300C.
[0089] The several heddle-holding elements 322 of each conveyor portion 302A, 302B, 302C,
304A, 304B or 304C follow the same closed transport path 306 which has, when seen
from the top, a polygonal shape, for instance a substantially rectangular shape with
four rounded corners, as shown on figure 1.
[0090] Each conveyor portion includes an endless belt 308 forming an endless member and
defining the closed transport path 306, when mounted on a frame 320 of the transport
device 12. Each endless belt 308 has the same rectangular shape as the closed transport
path 306.
[0091] Alternatively, a steel band or a chain can be used as an endless member, instead
of a belt. The endless member can take different shapes when not mounted on the frame
320 of the transport device 12.
[0092] The respective endless belts 308 of the three transport conveyors 300A, 300B, 300C
are arranged on top of each other. In particular, the upper conveyor portion 302A,
the upper conveyor portion 302B and the upper conveyor portion 302C are adjacent along
the reference axis Z and the lower conveyor portion 304A, the lower conveyor portion
304B and the lower conveyor portion 304C are adjacent along the reference axis Z.
Along this reference axis Z, the distribution of the conveyor portions is as follows,
from bottom to top : 304C, 304B, 304A, 302C, 302B, 302A. Each conveyor portion 304C,
304B, 304A, 302C, 302B, 302A extends at one different level along axis Z. The upper
conveyor portion 302C and the lower conveyor portion 304A are distant from each other
along axis Z, with a distance close to the length of the heddles 60.
[0093] In a non-represented variant of the invention, as the upper and lower heddle-holding
elements 322 are identical, the distribution of the conveyor portions around the top
frame 320 and around the bottom frame 320 along the reference axis Z axis does not
have the same alternation.
[0094] All endless belts 308 are preferably identical and include, on their inner surface,
some teeth 309 configured to interact with some wheels 318 provided with external
teeth and located at the four corners of the closed transport path 306. As visible
on figure 8, each endless belt 308 is also provided, on its external surface, with
three protrusions 310, regularly distributed around the periphery of the belt. Each
protrusion is equipped with a threaded hole 310B.
[0095] The heddles-transport device 12 also includes the frame 320, which forms guiding
rails 320A and 320B. These guiding rails are represented on figure 2 in dotted lines
and on figure 9 in solid lines. They extend parallel to the four rectilinear portions
of the closed transport path 306 and are interrupted at the level of the 4 corners.
[0096] For the upper conveyor portions 302A, 302B and 302C, three wheels 318 are located
at each corner of the closed transport path 306 and rotate around a common axis Z318
parallel to the reference axis Z. The wheels 318 are rotatably mounted on the frame
320 of the heddles-transport device 12. In particular, the corresponding rotation
axes Z318 of the wheels are defined by the frame 320, in the four corners of the closed
transport path 306.
[0097] In a first corner, a first servomotor 312A is connected via a first gear 316A to
a driving wheel 318A which is in meshing engagement with the endless belt 308 of the
upper conveyor portion 302A. The two other wheels 318 located in the first corner,
below the first driving wheel 318A, freely rotate around the corresponding common
axis Z318. In other words, the freely rotatable wheels are not directly connected
to a servomotor and their rotation is driven by the movement of the corresponding
endless belt 308.
[0098] In a second corner of the closed transport path 306, a second servomotor 312B drives,
via a second gear 316B, a second driving wheel 318B in meshing engagement with the
endless belt 308 of the second conveyor portion 302B. The two other wheels 318 located
in the second corner, above and below the second driving wheel 318B, freely rotate
around the corresponding axis Z318, as the two wheels located below the first driving
wheel 318A in the first corner.
[0099] In a third corner of the closed transport path 306, a third servomotor 312C drives,
via a third gear 316C, a third driving wheel 318C in meshing engagement with the endless
belt 308 of the third upper conveyor portion 302C. The other two wheels 318 located
in the third corner, above the third driving wheel 318C, freely rotate around the
corresponding axis Z318, as the two wheels located below the first driving wheel 318A
in the first corner.
[0100] As visible on figure 10, a shaft 319 defines the axis Z318 in the third corner and
connects in rotation the third gear 316C and the third driving wheel 318C, through
the other two wheels 318. Grabbing means 319A and 319B are provided at both ends of
the shaft 319, for connection to the third gear 316C and to the third driving wheel
318C respectively. The same approach is used in the first and second corners.
[0101] In the fourth corner of the transport path 318, three wheels 318 freely rotate around
a corresponding axis Z318, as the two wheels located below the first driving wheel
318A in the first corner.
[0102] The same approach is implemented at the level of the lower conveyor portions 304A,
304B and 304C where three servomotors 314A, 314B and 314C are used, respectively in
the same corners as servomotors 312A, 312B and 312C and drive non-represented driving
wheels. The servomotors 312A, 312B, 312C, 314A, 314B and 314C are mounted on the frame
320. The servomotors 312A, 312B, 312C, 314A, 314B and 314C are separately driven.
The servomotors 312A, 312B, 312C are electrically synchronized by the controller 16
respectively with the servomotors 314A, 314B, 314C, preferably with no direct mechanical
link between them. Preferably the upper conveyor portions 302A, 302B, 302C respectively
follow the same movement as the lower conveyor portions 304A, 304B, 304C.
[0103] The wheels 318 arranged in a corner of the closed transport path 306 define, at the
level of the upper conveyor portions 302A, 302B, 302C, a first set of wheels rotatable
with respect to the frame 320 of the heddles-transport device 12 around a common axis
Z318 and, at the level of the lower conveyor portions 304A, 304B, 304C, a second set
of wheels rotatable around the same common axis Z318. Each wheel of a set of wheels
cooperates with a different endless belt 308. The number of wheels 318 in each set
of wheels equals the number of transport conveyors of the heddles-transport device
12. In other words, a set of wheels cooperates with one endless belt 308 of all transport
conveyors 300A, 300B and 300C. In the embodiment of figures 1 to 10, this number is
three.
[0104] At the level of the upper conveyor portions 302A, 302B, 302C three sets of wheels
318 includes a driving wheel 318A, 318B or 318C and two freely rotatable wheels. The
fourth set of wheels includes three freely rotatable wheels 318. The same applies
at the level of the lower conveyor portions 304A, 304B, 304C.
[0105] The servomotors 312A, 312B, 312C, 314A, 314B and 314C form respective drives for
the first, second and third transport conveyors 300A, 300B and 300C.
[0106] Several heddle-holding elements 322 are secured to the endless belt 308 of each conveyor
portion 302A, 302B, 302C, 304A, 304B, 304C of each conveyor 300A, 300B, 300C. By convention,
a heddle-holding element 322 secured to the endless belt 308 of an upper conveyor
portion 302A, 302B, 302C is an upper heddle-holding element and a heddle-holding element
322 secured to the endless belt 308 of a lower conveyor portion 304A, 304B, 304C is
a lower heddle-holding element. The number of upper heddle-holding elements 322 of
a conveyor is the same as the number of lower heddle-holding elements 322 of the same
conveyor. All the transport conveyors 300A, 300B, 300C have the same number of heddle-holding
elements 322.
[0107] Advantageously, the upper and lower heddle-holding elements 322 are identical, except
for their orientation along the reference Z axis. Advantageously, the heddle-holding
elements 322 are identical to heddle-support elements 122.
[0108] All heddle-holding elements 322 are movable along the same closed transport path
306 and are mounted on the corresponding endless belt 308 by a respective screw 324.
More precisely, each heddle-holding element 322 is mounted on a protrusion 310, by
a screw 324 threaded in the corresponding threaded hole 310B of the protrusion 310.
On each corresponding endless belt 308, the number of protrusions 310 equals the number
of heddle-holding elements 322.
[0109] As for the heddle-support elements 122 of the heddles-sorting device 10, the heddle-holding
elements 322 work by pairs, a pair of heddle-holding elements 322 being formed by
an upper heddle-holding element 322 and a lower heddle-holding element 322 aligned
on a same axis parallel to the reference axis Z and configured for holding together
a single heddle 60 with its axis A60 parallel to the reference axis Z.
[0110] By construction, the endless belts 308 of one transport conveyor are configured to
transport individual heddles different from the individual heddles transported by
endless belts of the other two transport conveyors. By "different", it is meant that
the heddles transported by the endless belts 308 of a transport conveyor are not transported
by the endless belts of the other transport conveyors, even if all heddles are of
the same type.
[0111] Preferably, the heddle-support elements 122 and heddle-holding elements 322 are identical.
They only differ by the part of the heddle module they belong to, i.e. the heddles-sorting
device 10 for the heddle-support elements 122 and the heddles-transport device 12
for the heddle-holding elements 322.
[0112] In the following description, a part of a heddle-holding element 322 identical to
a part of a heddle-support element 122 is designated by the same reference plus 200.
[0113] In particular, each heddle-holding elements 322 includes a polymer body 326, which
forms upper and lower guiding parts 328 and 330 configured to slide within slots 332
and 334 respectively defined by the guiding rails 320A and 320B.
[0114] Alternatively, the body 326 of a heddle-holding element 322 can be made of another
material, e.g. metal.
[0115] Each heddle-holding element 322 also includes a pin 336 equipped with a nail 338
and loaded by a spring 340 towards a return position. The springs 340 of the upper
heddle-holding elements 322 urge the corresponding pins 336 upwardly, whereas the
springs 340 of the lower heddle-support elements 322 urge the corresponding pins 336
downwardly.
[0116] Each body 326 is provided with three superimposed bores 326B adjacent to one another
along the reference axis Z, one screw 324 being received in one of these bores, depending
on which belt 308 the heddle-holding element 322 is secured. More precisely, a screw
324 crosses the upper bore 326 of a first heddle-holding element 322 secured to the
endless belt 308 of the first conveyor 300A, a screw 324 crosses the intermediate
bore 326 of a second heddle-holding element 322 secured to the endless belt 308 of
the second conveyor 300B and a screw 324 crosses the lower bore 326 of a third heddle-holding
element 322 secured to the endless belt 308 of the third conveyor 300C.
[0117] An internal surface 326C forming an end of a recess 326A of each heddle-holding element
322 thus faces three belts 308, namely one belt 308 of each transport conveyor.
[0118] The pins 336 work as the pins 136 of the heddle-support elements 122 for loading
and unloading a heddle on or from the heddles-transport device 12 and at the transport
transfer position P3, they are piloted by release means 362 similar to the release
means 162.
[0119] In particular, the heddle-holding elements 322 are grouped by pairs of two vertically
aligned heddle-holding elements 322, i.e. two heddle-holding elements aligned to hold
a heddle 60 with its axis A60 parallel to the reference axis Z. The two heddle-holding
elements 322 of a pair are respectively secured to the endless belts 308 of the top
and bottom portions of a conveyor 300A, 300B, and 300C.
[0120] When a heddle must be moved from the sorting transfer position P2 to the transport
transfer position P3, the release means 362 actuate the pins 336 of the pair of heddle-holding
elements 322 located at the transport transfer position P3. In this configuration
the release means 362 pushes the pins 336 against their spring 340. The nails 138
of the pair of heddle-support elements 122 in the sorting transfer position P2 overlap
the nails 338 of the pair of heddle-holding elements 322 in the transport transfer
position P3. The nails 138 and 338 are located at different heights along the reference
axis Z and aligned along the longitudinal axis A60 of a heddle transferred between
the positions P2 and P3.
[0121] Advantageously, three heddle-holding elements 322 are secured to each endless belt
308. Thus, three pairs of upper and lower heddle-holding elements 322 are secured
to each conveyor 300A, 300B and 300C.
[0122] In a non-represented variant of the invention, the number of heddle-holding elements
per endless belt 308 can be larger than or equal to three.
[0123] More precisely, three upper heddle-holding elements 322A1, 322A2 and 322A3 are secured
to the endless belt 308 of the first upper conveyor portion 302A, three upper heddle-holding
elements 322B1, 322B2 and 322B3 are secured to the endless belt 308 of the second
upper conveyor portion 302B and three other heddle-holding elements 322C1, 322C2 and
322C3 are secured to the endless belt 308 of the third upper conveyor portion 302C.
[0124] Advantageously, the heddle-holding elements 322Aj, 322Bj and 322Cj are arranged alternately
along the closed transport path 306 with the same distribution along the whole transport
path, with j equal to 1, 2 or 3. In other words, each heddle-holding element of a
first conveyor is adjacent along the closed transport path 306 with a heddle-holding
element of a second conveyor and with a heddle-holding element of a third conveyor.
[0125] The pairs of heddle-holding elements 322 are configured to be successively loaded
with one heddle at the transport transfer position P3.
[0126] Preferably, the heddle-holding elements 322Aj, 302Bj and 302Cj are regularly distributed
along the closed transport path 306. In other words, the heddle-holding elements 322Aj,
302Bj and 302Cj are regularly distributed along their corresponding belt 308.
[0127] A similar distribution of lower heddle-holding elements 322 is used at the level
of the lower conveyor portions 304A, 304B, 304C.
[0128] Thus, at the level of the upper conveyor portions 302A, 302B, 302C and at the level
of the lower conveyor portions 304A, 304B, 304C, each heddle-holding element 322 secured
to one endless belt 308 is located, along the closed transport path 306, between two
other heddle-holding elements 322 secured to the two other endless belts and the pairs
of heddle-holding elements 322 are alternately distributed along the whole closed
transport path 306 with the same distribution. An upper heddle-holding element 322
is aligned along the reference axis Z with a lower heddle-holding element 322 of the
same transport conveyor so that their nails 338 are aligned along the reference axis
Z.
d322 denotes a distance, along the closed transport path 306, between two adjacent
harness-holding elements 322 secured to a given endless belt 308.
[0129] The heddles-transport device 12 is configured to carry a heddle 60 loaded at the
transport transfer position P3, where a heddle 60 has been loaded onto the heddle-transport
device 12, to a threading position P5, where a yarn from the warp-clamping frame 24
is inserted into the eyelet 64 of this heddle by the thread-insertion device 18. The
thread-insertion device 18 is typically a gripper having a reciprocate linear movement
along a threading path passing through the heddle eyelet 64 of a heddle 60 held by
a heddle-holding element 322 at the threading position P5, catching a warp yarn of
the warp-clamping frame 24 and moving back with the warp yarn through the heddle 60.
[0130] The spacing between two heddle-holding elements 322 carried by the same endless belt
308 is equal to the distance, measured along the closed transport path 306, between
the transport transfer position P3 and the threading position P5. Thus, two pairs
of such heddle-holding elements 322 carried by the same transport conveyor can be
located at the same time in these two positions, like the pairs including heddle-holding
elements 322B1 and 322B2 in the configuration of figures 1 to 3.
[0131] The heddles-transport device 12 is also configured to carry each heddle 60 from the
threading position P5 to one of several discharge positions P6, a discharge position
being defined in front of each support rod 202 along direction Y.
[0132] The transport transfer position P3, the threading position P5 and each discharge
position P6 are distributed on different straight portions of the polygonal closed
transport path 306. The closed transport path 306 goes successively through the transport
transfer position P3, through the threading position P5 and through the discharge
positions P6.
[0133] As shown by the single arrow A2 on figure 1, the servomotors 312A, 312B, 312C, 314A,
314B and 314C can drive the endless belts 308, and thus the heddle-holding elements
322 , in one direction only, along the closed transport path 306, namely from the
transport transfer position P3 to the threading position P5 and then to the discharge
positions P6, then to the transport transfer position P3 without passing again at
the threading position P5.
[0134] In the direction of movement along the closed transport path 306, represented by
the arrow A2, the distribution of heddle-holding elements 322 is as follows: 322C1,
322B1, 322A1, 322C2, 322B2, 322A2, 322C3, 322B3, 322A3.
[0135] Several zones can be defined along the closed transport path 306.
[0136] A first waiting zone is defined along the closed transport path 306, between the
transport transfer position P3 and the threading position P5.
[0137] A discharge zone DZ is defined along axis X, along the closed transport path 306,
between the first discharge position P6 aligned with the first support rod 202, and
the last discharge position P6 aligned with the twentieth support rod 202
20. The first discharge position is the discharge position P6 that a heddle-holding
element 322 reaches first when moving, from the threading position P5, in the direction
of the arrow A2. The last discharge position is the discharge position P6 that a heddle-holding
element 322 reaches at the latest when moving, from the threading position P5, in
the direction of the arrow A2. In other terms, the discharge zone DZ extends from
the first discharge position P6 to the last discharge position P6. In particular,
a first discharge subzone DZ1 is defined between the first discharge position P6 aligned
with the first support rod 202, and the tenth discharge position P6 aligned with the
tenth support rod 202
10. A second discharge subzone DZ2 is defined between the eleventh discharge position
P6 aligned with the first support rod 202
11 and the twentieth discharge position P6 aligned with the tenth support rod 202
20.
[0138] LDZ denotes the length of the discharge zone DZ, which is its dimension along the
closed path 306.
[0139] The distance d322 along the closed transport path 306 between two adjacent harness
component-holding elements 322 secured to a given endless belt 308 is greater than
the length LDZ of the discharge zone DZ along the closed transport path 306.
[0140] A second waiting zone is defined between the last discharge position P6 and the transport
transfer position P3.
[0141] In the configuration of figures 1 to 3, the heddle-holding elements 322A2 and 322C3
are each in a discharge position P6, respectively a first discharge position corresponding
to the first support rod 202, and located in the first discharge subzone DZ1 and a
second discharge position corresponding to the twentieth support rod 202
20 and located in the second discharge subzone DZ2.
[0142] The heddles-discharging device 28 includes two pushers 282 and 284, each pusher being
movable relative to the frame 320 parallel to the reference axis Y between a retracted
position represented in solid lines on figure 1 and an extended position represented
in dotted line in the lower portion of figure 1, for the pusher 282. Each pusher moves
independently of the endless belts 308. In other words, the pushers are not co-moved
with the heddle-holding elements 322 along the transport path 306.
[0143] Each pusher 282, 284 is constantly aligned, along a direction parallel to the reference
axis Y, with at most half of the several discharge positions P6, that is ten of the
twenty discharge positions P6 represented by the twenty support rods 202
k in the current embodiment. In the example of the figures, each pusher 282, 284 is
constantly aligned with ten adjacent discharge positions P6 which belong either to
the first discharge subzone DZ1 or to the second discharge subzone DZ2. Each pusher
282, 284 is configured to push a heddle from a heddle-holding element 322 located
at one of the ten discharge positions P6 onto one of the ten support rods 202
k in one of the two discharge subzones. In other words, each pusher 282 or 284 constantly
extends at the level of several discharge positions and covers at most half of the
discharge positions P6.
[0144] In practice, each pusher 282, 284 can be made of a pair of two pusher-elements, aligned
along a direction parallel to the reference axis Z, as shown with top pusher-element
282T and bottom pusher element 282B of pusher 282 on figure 3. The other pusher 284
as the same structure with a pair of non-represented top and bottom pusher elements.
Thus, a group of top pusher elements, 282T and equivalent, is located next to the
upper conveyor portions 302A, 302B and 302C and another group of pusher elements,
282B and equivalent, is located next to the lower conveyor portions 304A, 304B and
304C.
[0145] Three sensors 352A, 352B and 352C are integrated within the heddles-transport device
12 and allow knowing the position of each endless belt 308 of the upper conveyor portions
302A, 302B and 302C relative to the frame 320, i.e. knowing, at any time, the position
of each upper heddle-holding element 322 along the closed transport path 306. Similarly,
three sensors 354A, 354B and 354C are integrated within the heddles-transport device
12 and allow knowing the position of each endless belt 308 of the lower conveyor portions
304A, 304B and 304C relative to the frame 320, i.e. knowing, at any time, the position
of each lower heddle-holding element 322 along the closed transport path 306.
[0146] The sensors 352A, 352B, 352C, 354A, 354B and 354C are preferably encoders associated
to the drives of the transport conveyors 300A, 300B and 300C.
[0147] The controller 16 is connected to the heddles-detection device 14 and receives the
signal S14.
[0148] The controller 16 is also connected to the sensors 352A, 352B, 352C, 354A, 354B and
354C and receives from these sensors six control signals S352A, S352B, S352C, S354A,
S354B and S354C.
[0149] The controller 16 is also connected to the drives 112, 114, 312A, 312B, 312C, 314A,
314B and 314C, so that it can pilot the movement of the endless belts 108 and 308
respectively along the closed sorting path 106 and along the closed transport path
306. The controller 16 also controls the drives of the heddles-transfer device 26
and of the heddles-discharging device 28.
[0150] The controller 16 includes a processor 16A configured to process information coming
from the heddles-detection device 14 so that it can determine the heddle type, among
left heddle and right heddle, from the parameter detected for each heddle by the heddles-detection
device 14. The processor 16A can also determine a heddle sequence, that is a succession
of heddle types among left heddle and right heddle, from a drawing-in draft. The processor
16Acan also process information from the encoders of the heddles-sorting device 10
and is configured to control the movements of the heddles-sorting conveyor 100 according
to the heddle sequence, in such a way that it automatically feeds a correct heddle,
namely a left heddle 60L or a right heddle 60R, at the sorting transfer position P2,
ready to be transferred to the transport transfer position P3. The controller 16 also
includes a memory 16B where a heddle sequence and the configuration of each pair of
heddle-support elements 122 are stored.
[0151] A configuration of a pair of heddle-support elements 122 is representative of whether
this pair is free, i.e. does not support a heddle 60, whether this pair supports a
left heddle 60L or whether this pair supports a right heddle 60R.
[0152] The drawing-in draft defines the heddle sequence with which the heddles shall be
brought to the threading position P5 and, from there, to the heddles-receiving module
20. Since duplex heddles 60 are used, the heddle sequence consists of a sequence of
left heddles 60L and right heddles 60R, because each support rod 202
k shall be fed with a regular alternation of left and right heddles.
[0153] When a heddle 60 is separated from the heddle stack 6 by the heddles-separating device
8, the controller 16 controls the heddles-sorting device 10 in order to bring a free
pair of heddle-support elements 122 into the feeding position P1. A free pair of heddle-support
elements 122 is a pair which does not support a heddle. It may also be called an empty
pair of heddle-support element. It is devoid of a heddle 60.
[0154] The actual configuration of the pair of heddle-support elements 122, i.e. the fact
that it is free or not, is controlled by a non-represented inductive sensor, which
senses the position of at least one of the pins 136 of this pair. The position of
the pin 136 depends on whether its nail 138 abuts against the end loop 62 of a heddle
60 or against the body 126 of this heddle-support element. This position can be detected
by the inductive sensor and the corresponding information also provided to the controller
16.
[0155] At the beginning of the drawing-in process, the default setting for the configuration
of the pair of heddle-support elements 122 is equal to "free".
[0156] When a heddle 60 is separated from the stack 6, it is detected by the heddles-detection
device 14, which sends to the controller 16 an information, for instance a partial
picture of this heddle, included in the signal S14. The controller 16 processes this
information in order to determine at least the left or right geometry of this heddle
60.
[0157] When the separated heddle is loaded on the pair of heddle-support elements 122 present
at the feeding position P1, the information relating to the fact that this heddle
is a left heddle 60L or a right heddle 60R is associated to the location of the pair
of support elements 122 along the two belts 108. This information is stored in the
memory 16B.
[0158] Therefore, at all time, the controller 16 knows which pairs of heddle-support elements
122 are free, which pairs heddle-support elements 122 support a left heddle 60L and
which pairs heddle-support elements 122 support a right heddle 60R. Moreover, the
controller 16 knows the position of each pair of heddle-support elements 122 along
the sorting path 108.
[0159] During a drawing-in process, the heddles-sorting device 10 is loaded with heddles.
In practice, heddles 60 are separated, one by one, from the stack 6 and placed, one
by one, in the detection position P4. For each separated heddle 60, a signal S14 is
sent to the processor 16A of the controller and the memory 16B is updated with the
information contained in, or derived from, the signal S14 about the left or right
geometry of this heddle in association with the pair SEi of heddle support-elements
122, with i an integer between 1 and 24, that will be loaded with this heddle : for
this pair SEi of heddle support-elements 122, the free configuration is replaced by
right heddle 60R or by left heddle 60L. When the heddle is loaded onto the pair SEi
of heddle support-elements 122, release means 162 are activated for this pair SEi
of heddle support-elements 122.
[0160] As an example, one considers a heddle sequence, starting at a 15
th heddle and where the heddles-transport device 12 must provide left and right heddles
on different support rods 202
1, 202
2, 202
3 and 202
4 of the heddles-receiving module 20 as specified here below:
... ... ... ...
15th heddle : right heddle 60R - support rod 2023
16th heddle : right heddle 60R - support rod 2021
17th heddle : right heddle 60R - support rod 2022
18th heddle : left heddle 60L - support rod 2021
19th heddle : left heddle 60L - support rod 2023
20th heddle : right heddle 60R - support rod 2024
21th heddle : right heddle 60R - support rod 202,
22th heddle : left heddle 60L - support rod 2022
23 ...
[0161] When the 15
th heddle is to be loaded on the heddles-transport device 12, the heddles-sorting device
10 is already loaded with a number of heddles, as shown in table 1 here below where
"SE1" to "SE24" represent the twenty four pairs of heddle-support elements (SE) on
the sorting conveyor 100, "60L" represents a left heddle, "60R" represents a right
heddle and "FREE" means that no heddle is supported by the corresponding pair SEi
of heddle-support elements 122, with i an integer between 1 and 24.
[0162] In this table 1, which corresponds to the information memorized in memory 16B, line
P1 identifies a pair SEi of heddle-support elements in the feeding position P1 and
line P2 identifies another pair of heddle-support elements 122 in the sorting transfer
position P2. In this example, for these positions of the sorting belts 108 on the
sorting path 106, these two pairs are respectively SE1 and SE13.

[0163] Starting from the configuration shown here above of the sorting device 10, the following
sequence is implemented.
[0164] For the 16
th heddle, since a right heddle 60R is needed at the transfer position, SE10 which supports
the closest right heddle 60R is brought into the sorting transfer position P2, which
brings SE22, which is free, in the feeding position P1, ready for feeding the next
heddle onto the sorting device 10. A left heddle 60L is loaded on SE22. The right
heddle 60R of SE10 is transferred by the pusher 262 onto the heddle-holding element
which is at the transport-transfer position P3. For this transfer, the release means
362 are activated. SE10 is now in free configuration. This is shown in the second
and third columns of table 2 here below. The memory 16B is updated for SE10 and SE22.
[0165] This goes on for the next heddles, with the same approach.
[0166] For the 17
th heddle, since a right heddle 60R is needed, SE7 could be brought into the sorting
transfer position P2 but this would bring SE19 into the feeding position P1, whereas
SE19 already supports a right heddle 60R. Alternatively, the controller 16 could select
SE17, which supports the second closest right heddle 60R and bring it into the sorting
transfer position P2 but this would bring SE5 into the feeding position P1, whereas
SE5 already carries a left heddle 60L. Then, the controller 16 selects a third option,
where SE4, which supports the third closest right heddle 60R is brought into the sorting
transfer position P2 whereas SE16, which is free, is brought into the feeding position
P1. This is shown in the fourth and fifth columns of table 2 here below.
[0167] For the 18
th heddle, the same strategy is applied. A rotation bringing SE5 into the transfer position
could not work since SE17 is already loaded with a right heddle 60R. Then, the controller
16 selects another approach where SE1 is brought into the sorting transfer position
P2 and SE13, which is free, is brought into the feeding position P1. This is shown
in the sixth and seventh columns of table 2 here below.
[0168] This is summarized in the table 2 here below, which also covers the 19th heddle,
in its eighth and ninth columns.

[0169] This goes on for the next heddles, with the same approach.
[0170] With this process, the heddle-transport device 12 has been successively loaded and
has fed the receiving module 20 with the predetermined heddle sequence.
[0171] Refering to the example given above, the 15
th right heddle 60R has been transported by a pair of heddle-holding elements 322 onto
the threading position P5, drawn-in with a warp yarn when at the threading position
P5, and then transported onto the discharge position P6 corresponding to the support
rod 202
3 in which the pusher 282 has pushed the 15
th right heddle onto the support rod 202
3. The 16
th right heddle 60R has been has been transported by another pair of heddle-holding
elements 322, which was adjacent to the pair which has transported the 15
th heddle, onto the threading position P5, drawn-in with a warp yarn when at the threading
position P5, and then transported onto the discharge position P6 corresponding to
the support rod 202, in which the pusher 282 has pushed the 16
th right heddle onto the support rod 202
1
[0172] This shows that the controller 16 can apply a strategy in order to selectively bring
one pair SEi of heddle-support element 122 at the sorting transfer position P2, while
making sure that the opposite pair of heddle-support elements, SEi+12 or SEi-12, is
free, so that it can be brought to the feeding position P1 to be loaded with a heddle
60.
[0173] As a summary, the heddle sequence states the type of the next heddle needed at the
sorting transfer position P2 and the controller 16 synchronically drives the sorting
belts 108 in order to move into the sorting transfer position P2 the heddle with the
correct heddle type, i.e. a left or right heddle, which is the closest from the transfer
position along the closed sorting path 106, regardless of the direction A1 of movement
along the sorting path 106, at the condition that this movement of the sorting conveyor
100 also brings a free pair of heddle-support elements 122 at the feeding position
P1. If not, the controller 16 controls the heddles-sorting device 10 to move the second
closest heddle of the right type into the sorting transfer position P2, at the condition
that this also brings a free pair of heddle-support elements 122 at the feeding position
P1. This can be iterated until a correct configuration of the sorting conveyor 100
is reached. In other words, if, from the configuration of the heddles 60 on the heddle-support
elements 122 of the heddle sorting device 10, at least two different movements of
the sorting conveyor 100 are possible to place a free heddle-support element 122 in
the feeding position P1, and, at the same time, a heddle-support element 122, supporting
a heddle whose detected parameter corresponds to the predetermined heddle type depending
on the heddle sequence in the sorting transfer position P2, then the controller 16
controls movement of the sorting conveyor 100 to place, at the sorting transfer position
P2, the heddle-support element 122 holding a heddle whose detected parameter corresponds
to the type of heddle needed by the heddle sequence and being the closest to the sorting
transfer position P2.If two movements of same amplitude are possible, i.e. if two
equal displacements of two heddles 60L or 60R of the selected type are possible, a
main direction of displacement can be selected by the controller 16.
[0174] If the movement of any correct heddle present on the sorting device 10 into the sorting
transfer position P2 doesn't bring a free pair of heddle-support elements 122 at the
feeding position P1, the controller 16 synchronically drives the sorting belts 108
in order to move the correct heddle which is the closest from the transfer position
along the closed sorting path 106 and during transfer of this heddle onto the transport
device 12, no heddle is loaded onto the sorting device at the feeding position P1.
[0175] This optimization of the movements of the pairs SEi of heddle-support elements 122
is possible because the controller 16 knows from its memory 16B and in real time for
each pair SEi of heddle-support elements 122 where this pair SEi is along the path,
if it is free, if it supports a left heddle 60L or if it supports a right heddle 60R
and because movements of the sorting conveyor 100 in both directions is possible,
as shown by arrow A1.
[0176] As a summary, the method explained here above includes at least the following steps
consisting in:
- a) moving the heddle-support elements 122 of the sorting device 10 along the sorting
path 106 up to placing a free heddle-support element at a feeding position P1;
- b) separating a heddle 60 from the at least one stack 6;
- c) detecting a parameter representative of the geometry of the heddle, the parameter
differing depending on whether the heddle is a left heddle or a right heddle;
- d) feeding the free heddle-support element 122 located at the feeding position P1
with the heddle, at the feeding position P1;
- e) moving the heddle-support elements 122 of the heddles-sorting device along the
sorting path 106 in order to place, in the sorting transfer position P2, a heddle-support
element holding a heddle whose detected parameter corresponds to a predetermined value,
the predetermined value depending on the heddle sequence; and
- f) moving the heddle out of the heddle-support element 122 located at the sorting
transfer position P2 onto a heddle-holding element 322 of the heddles-transport device
12 located at a transport transfer position P3.
[0177] The order of the steps a) to f) is not imperative. For instance, step b) and/or c)
can occur before step a). For instance, step c) can occur before or after step b).
Preferably the end of step a) occurs at the same moment as the end of step e).ln other
words, steps a) and e) end at the same moment.
[0178] In the present description, HEAi, designate pairs of heddle-holding elements (HE)
of the first conveyor 300A, HEBi, designate pairs of heddle-holding elements of the
second conveyor 300B and HECi designate pairs of heddle-holding elements of the third
conveyor 300A, with i an integer between 1 and 3. A pair HEAi includes the upper heddle-holding
element 322Ai, a pair HEBi includes the upper heddle-holding element 322Bi and a pair
HECi includes the upper heddle-holding element 322Ci, with i an integer between 1
and 3.
[0179] When a pair HEAi of heddle-holding elements 322 has been loaded with a heddle 60
in the transport transfer position P3, then it can be moved by the two belts of the
first conveyor 300A into a waiting position located in the first waiting zone, as
shown on figure 1 for the pair HEA1 including the upper heddle-holding element 322A1.
[0180] This waiting position is determined in view of the discharge position P6 chosen for
another pair of holding elements moved by the same conveyor 300A, namely the pair
HEA2 including the upper heddle-holding element 322A2, which is in the first discharge
position P6, aligned with the first support rod 202
1.
[0181] On the other hand, from the first waiting zone, all pairs HEAi, HEBi and HECi of
heddle-holding elements 322 are successively moved to the threading position P5. As
mentioned here-above, when one such pair is in this position, another pair moved by
the same conveyor is in the transport transfer position P3, ready to be loaded with
a heddle 60.
[0182] After a heddle 60 carried by one pair of heddle-holding elements 322 has be threaded
at the threading position P5, it is moved in one of the discharge positions P6, depending
on the drawing-in draft.
[0183] Then, one of the two pushers 282 and 284 is used to push the heddle out of the pair
of heddle-holding elements 322 onto one of the support rods 202 aligned with the discharge
position P6 where this pair of heddle-holding elements has been stopped.
[0184] Once it has been discharged from its heddle 60, each pair HEAi, HEBi or HECi of heddle-holding
elements 322 moves into the second waiting zone. From the second waiting zone, it
is brought back into the transport transfer position P3, when a new heddle 60 must
be transferred on this pair of heddle-holding elements.
[0185] The respective movements and stops of the pairs HEAi, HEBi or HECi of heddle-holding
elements 322 along the closed transport path 306 is controlled by the controller 16
which commands the drives 312A, 312B, 312C, 314A, 314B, 314C. For each transport conveyor
300A, 300B or 300C, these movements between two stops along the closed transport path
306 can vary in amplitude, acceleration and speed.
[0186] Advantageously, these drives are actuated at the same time, so that all endless belts
308 are moved at the same time. Thus, the transport conveyors 300A, 300B and 300C
move and stop at the same time, which reduces the risks of collision between the different
pairs of heddle-holding elements.
[0187] The amplitude and speed of the movements of each pair of endless belts 308 of a same
transport conveyor 300A, 300B or 300C depend on the position of each belt along the
closed transport path 306. For instance, a longer movement is needed if a heddle 60
needs to be brought in front of the last discharge position P6 than if it needs to
be brought in front of the first discharge position. At any time, the movements of
the transport conveyors 300A, 300B and 300C may have different speeds and accelerations.
[0188] Advantageously, to reduce the amplitude of the accelerations of each belt, after
a heddle 60 carried by one pair of heddle-holding elements 322 has be threaded at
the threading position P5, depending on the drawing-in draft and the discharge position
of this heddle 60, it is moved in one of the discharge positions P6 of the first discharge
subzone DZ1, where it is unloaded by the pusher 282, or at the tenth discharge position
P6, where it waits for further movement before unloading. This pair of heddle-holding
elements 322 is then respectively moved at the twentieth discharge position P6, where
it waits for further movement, or in one of the discharge positions P6 of the second
discharge subzone DZ2, where it is unloaded by the pusher 284. Thus, a pair of heddle-holding
elements 322 can be at one of the discharge positions P6 without activation of the
pusher 282 corresponding to this discharge positions P6.
[0189] Since a pair of heddle-holding elements 322 is present at the transport transfer
position P3 when another pair of heddle-holding elements is present at the threading
position P5, threading and transfer occur substantially at the same time for two pairs
of heddle-holding elements carried by the same conveyor.
[0190] Because of the alternation of the pairs of heddle-holding elements along the closed
transport path 306, even if the endless belts of the respective transport conveyors
300A, 300B and 300C can be separately driven, their movement must take into consideration
the position of the other endless belts, more particularly of the pairs of heddle-holding
elements 322 carried by these other belts.
[0191] In view of the distribution of the positions P3, P5 and P6 along the closed transport
path 306, each pair of endless belts 308 of one conveyor can carry two heddles 60
at the same time, one of these heddles being loaded on the pair of heddle-holding
elements located at the transport transfer position P3 or waiting in the first waiting
zone, whereas the second heddle is carried by the pair of heddle-holding elements
located at the threading position P5 or ready to discharge in one of the discharge
positions P6.
[0192] According to an advantageous aspect of the invention, the distance between the endless
belts 108 of the upper sorting conveyor portion 102 and the lower sorting conveyor
portion 104 along the reference axis Z is adjustable in order to adapt to different
heddle lengths. With this respect, no part of the frame 120 of the heddles-sorting
device 10 is located between these upper and lower sorting conveyor portions 102 and
104, so that nothing hinders a vertical relative movement between these portions.
In particular, an upper frame of the heddles-sorting device 10, which is a part of
the frame 120 supporting the upper sorting conveyor portion 102, and a lower frame
of the sorting device 10, which is also a part of same the frame 120 supporting the
lower sorting conveyor portion 104, are not connected by mechanical links within the
volume located between the upper sorting conveyor portion 102 and the lower sorting
conveyor portion 104.
[0193] According to another advantageous aspect of the invention, the distance between the
endless belts 308 of the upper conveyor portion 302A, 302B and 302C, on the one hand,
and the endless belts 308 of the lower conveyor portion 304A, 304B and 304C, along
the reference axis Z is also adjustable in order to adapt to different heddle lengths.
With this respect, no part of the frame 320 of the heddles-transport device 12 is
located between these upper and lower portions 302A, 302B, 302C, 304A, 304B and 304C,
so that nothing hinders a vertical relative movement between these portions. In particular,
an upper frame of the heddles-transport device 12, which is a part of the frame 320
supporting the upper conveyor portions 302A, 302B and 302C, and a lower frame of the
sorting device 10, which is also a part of the same frame 320 supporting the lower
conveyor portions 304A, 304B and 304C, are not connected by mechanical links within
the volume located between the upper conveyor portion 302A, 302B and 302C and the
lower conveyor portion 304A, 304B and 304C.
[0194] In the second embodiment of the invention represented on figures 11 and 12, components
of the heddle module 30 and of the drawing-in machine 2 of the invention similar to
the ones of the first embodiment bear the same references. If a reference is mentioned
in this description with respect to the second embodiment without being shown on figures
11 and 12 or if a reference is shown on these figures without being mentioned in the
description for the second embodiment, it corresponds to the element with the same
reference for the first embodiment. On figures 11 and 12, for the sake of clarity,
upper and lower heddle-holding elements 322 are shown without any hold heddles.
[0195] Hereafter, one lists mainly the differences between the first and second embodiments.
[0196] In this second embodiment, the heddles-transport device 12 does not include three
transport conveyors but only one transport conveyor 300 with a unique upper portion
having a unique upper endless belt 308 and a unique lower portion having a unique
endless belt 308. Each endless belt 308 carries heddle-holding elements 322, which
are not identical to the heddle-support elements 122 of the heddles-sorting device
10, which is the same as the heddles sorting device of the first embodiment and not
further described.
[0197] Upper and lower heddle-holding elements 322 are defined as in the first embodiment.
The number of upper heddle-holding elements 322 of the unique conveyor 300 is the
same as the number of lower heddle-holding elements 322 of this conveyor. The upper
and lower heddle-holding elements 322 are identical, but for their orientation along
the reference Z axis. The upper and lower heddle-holding elements 322 form pairs of
heddle-holding elements.
[0198] The heddle-holding elements 322 each include a body 326, a pin 336, a nail 338 and
a spring 340 for urging the pin into a default position.
[0199] The single conveyor 300 of the heddles-transport device 12 defines a closed transport
path 306 for the heddle-holding elements 322. It can be made according to the teachings
of
WO92/05303A1.
[0200] In this second embodiment, the heddle-holding elements 322 are secured side by side
along the closed transport path 306 followed by the two belts 308 of the upper and
lower portions of the transport conveyor 300.
[0201] For the rest, the controller 16 controls the heddles-sorting device 10 as explained
for the first embodiment.
[0202] In a non-represented variant of the invention, instead of belts, the sorting conveyor
100 can be a rotating carousel with several heddle-support elements at the end of
several arms driven by a rotating head.
[0203] In another non-represented variant of the invention, the heddles-sorting device 10
can include several sorting conveyors 100 covering different sorting paths, which
implies that the heddles-sorting device 10 serves several sorting transfer positions
P2, preferably two sorting transfer positions P2, and that the heddle module 30 comprises
several transport transfer positions P3, preferably two transport transfer positions
P3.
[0204] In another non-represented variant of the invention, provided that the heddle-support
elements 122 firmly grip the heddles 60, the sorting conveyor 100 of the heddles-sorting
device 10 has a single portion, not an upper portion and a lower portion. This variant
can make use of the pistons mentioned in
WO00/11252A1.
[0205] In still another variant, the heddles-sorting device 10 can be provided with several
sorting conveyors or several pairs of sorting belts, for instance superimposed sorting
belts whose heddle-support elements move along the same sorting path, each sorting
belt transporting at least a heddle different from the heddles transported by the
other transport sorting belts, each sorting belt carrying several heddle-support elements
that are spaced along the sorting path, the heddle-support elements of the several
sorting belts being preferably alternately distributed along the sorting path.
[0206] In all embodiments, the heddles-detection device 14 can be used to detect improper
heddles 60, for instance heddles with an important wear, simplex heddles, deformed
heddles, etc. Such improper heddles can be eliminated by the sorting device 10, so
that they are not transferred to the heddles-transport device 12. In particular, the
closed sorting path 106 can pass at an ejection position, which is not a transfer
position. When an improper heddle is at the ejection position, some non-represented
ejection means, in particular a specific pusher, can be actuated to eject the improper
heddle out of the sorting belts 108.
[0207] In all embodiments, the number of support rods 202 or pairs of support rods 202 equipping
the receiving module 20 depends on the configuration of the heddles-receiving module
20 and of the pattern for the fabric to be woven on the loom. For instance, the heddles-receiving
module 20 can be equipped with less than twenty pairs of support rods 202, for instance
sixteen or twelve twenty pairs of support rods 202.
[0208] This ejection position can also be used to discharge all heddles carried on the sorting
conveyor 100 before changing the type of heddles to be processed, for instance before
changing the length of the heddles of the stack 6 and the vertical distance between
the upper and lower conveyor portions 102 and 104.
[0209] In another variant of the invention, several magazines can be used in the heddles-feeding
device 4. In such a case, several feeding positions are provided on the closed sorting
path 106 and several heddles-separating devices 8 are used. This brings the advantage
that feeding of the heddles-sorting device 10 is not interrupted when the operator
supplies a new stack 6 of heddles 60 to one magazine. This configuration can also
be used to selectively feed two heddles at the same time on the sorting conveyor 100
or to feed one heddle at a time, at one of the two feeding positions.
[0210] According to a non-represented variant of the invention, the heddles-detection device
14 has a field of view 144, which covers at least the first heddle of the stack 6,
which means that the heddles-detection device 14 detects if the heddle is a right
heddle or a left heddle before the heddle is separated from the stack 6.
[0211] According to a non-represented variant of the invention, the heddles-detection device
14 has a field of view 144, which covers heddles supported by several pairs of heddle-support
elements 122 around or next to the sorting transfer position P2. This information
allows the controller 16 to determine the closest heddle 60 corresponding to the type
of heddle to be transferred onto the heddles-transport device 12, in accordance with
the heddle sequence. Then, the controller 16 can drive the sorting conveyor 100 to
bring this specific heddle 60L or 60R into the sorting transfer position P2. With
this approach, there is no need to memorize the type of heddle of each pair Sei of
heddle-support elements 122 of the sorting device 10. With this approach, several
detection cameras 142 or sensors can be used in the heddles-detection device 14.
[0212] In another non represented variant of the invention, the closed transport path 306
includes several threading positions P5, each heddle being threaded only once at one
of these several threading positions P5.
[0213] In another non represented variant of the invention, the heddle sorting device 10
can feed a heddle transport device as described in
FR2930950A1.
[0214] Advantageously, the field of view of the heddles-detection device 14 covers heddles
60 before a separated heddle is transferred from the sorting transfer position P2
to the transport transfer position P3.
[0215] Instead of a camera, the heddles-detection device 14 can incorporate a light barrier
or a proximity sensor configured to derive a different information from the heddles,
depending on the left or right geometry of each heddle.
[0216] In another non-represented variant of the invention, two sorting transfer positions
can be provided on the sorting device 10 and two corresponding transport transfer
positions can be provided on the heddles-transport device 12. In such a case, the
closed sorting path 106 of the sorting conveyor 100 is straight between these two
sorting transfer positions and, for each endless belt 108 of the sorting conveyor
100, when one heddle-support element 122 is at the feeding position P1, another heddle-support
element is at the first sorting transfer position and still another heddle-support
element 122 is at the second transfer position. This allows optimizing the time needed
to load the heddles-transport device 12 with heddles.
[0217] In addition to the type of a heddle, left or right, the heddles-detection device
14 can detect several heddle parameters that may impact its drawing-in capabilities.
These parameters can be memorized and used for controlling the heddles-transport device
12 and/or the thread-insertion device 18. For example, the position of the eyelet
64 along a heddle can be used to adjust the height position of the heddle at the threading
position P5. This information can be provided to the main controller of the drawing-in
machine 2 or to a specific controller driving the different devices of the drawing-in
machine.
[0218] In all embodiments of the invention, the time period during which each holding element
322 stays at the threading position P5 can be adapted to the warp thread to be inserted
into the harness component held by the holding element. For instance, the insertion
can take longer for a coarse warp yarn than for a thin warp yarn. The succession of
left and right heddles at the threading position P5 during a drawing-in process corresponds
to the heddle sequence.
[0219] In all embodiments, the heddles are preferably transported at substantially the same
height level along the reference axis Z, when they are on the sorting device 10, and
at substantially the same height level along the reference axis Z, when they are on
the transport device 12. The dropwires are preferably transported at substantially
the same height level along the reference axis Z, when they are on the transport device
12.
[0220] In all embodiments, some additional sensors, for example proximity switches or cameras,
may be used to check the presence or absence of harness components on the harness
component-holding elements or of heddles on the heddle-support elements.
[0221] Reducing the interspace between the holding elements 322 in the waiting zone between
the transport transfer position P3 and the threading position P5 allows a quick movement
of the holding elements between these positions, thus a longer time can be spent at
the threading position P5, for this threading operation.
[0222] Alternatively, the waiting zones for the holding elements 322 can be provided just
after the transport transfer position P3, and not just before, and after the threading
position P5, and not before.
[0223] The warp threads that are drawn-in through the heddles can come from a warp beam
or from a bobbin.
[0224] The above-mentioned embodiments and variants of the invention can be combined within
the scope of the invention defined by the appended claims.
[0225] Irrespective of the embodiment or variant of the invention, the invention brings
at least the following advantages:
- The heddles-sorting device 10 can be used to automatically feed the heddles-transport
device 12 with the correct heddle sequence, starting with a single stack 6 of duplex
heddles or from several stacks of duplex heddles. This avoids the obligation of separating
heddles into right heddles and left heddles before installing the stack of heddles
on the heddles-feeding device 4 of the drawing-in machine. The complexity of the drawing-in
machine is reduced, since only one heddles-separating device is required.
- The closed sorting path 106 and the memorization in the controller 16 of the heddle
type and of the presence or absence of a heddle on a pair SEi of heddle-support elements
122 allows optimizing movements of the sorting conveyor 100 in both directions represented
by the double arrow A1. The time for feeding each heddle 60 at the sorting transfer
position P2 is reduced. Moreover, the regular distribution of the heddle-support elements
122 on the endless belts 108 allows placing one pair of heddle-support elements 122
at the feeding position P1 and one pair of heddle-support elements 122 at the sorting
transfer position P2, at the same time.
- The closed sorting path 106 and the layout of the heddles-sorting device 10 with several
heddle-support elements 122 interposed between the feeding position P1 and the sorting
transfer position P2 gives more possibilities to ensure that, amongst the several
heddles supported by the sorting conveyor 100, a heddle of the type needed by the
sequence can be placed at the sorting transfer position P2 at the same time as a free
pair of heddle-support elements 122 is based at the feeding position P1.
- The construction of the sorting conveyor 100 with endless members formed by belts
108 is simple and allows using a high number of heddle-support elements 122 in a reduced
volume.
- The oblong closed path 106 does not substantially increase the size of the drawing-in
machine 2 in a direction parallel to the reference axis Y.
- Since the number of heddle-support elements 122 on each belt 108 is greater than the
number of support rods 202 of the heddles-receiving module 20, the risk of not having,
on the sorting conveyor 100, a heddle with the geometry needed is reduced. This is
important since, otherwise, this would force the operator to eject some heddles out
of the sorting conveyor 100 for freeing some pairs of heddle-support elements 122
and getting new heddles 60 on the heddles-sorting device 10.
- The absence of mechanical link between upper and lower frames of the heddles-sorting
device 10 within the volume between upper and lower conveyor portions allows easy
access for the operator to any heddle 60 carried by the pair of sorting belts 108
and does not hinder height adjustment between the upper and lower heddle-support elements
122.