EP4219812A1 - Dispositif de formation de la foule d'un métier circulaire et métier circulaire équipé d'un tel dispositif - Google Patents

Dispositif de formation de la foule d'un métier circulaire et métier circulaire équipé d'un tel dispositif Download PDF

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Publication number
EP4219812A1
EP4219812A1 EP22154152.7A EP22154152A EP4219812A1 EP 4219812 A1 EP4219812 A1 EP 4219812A1 EP 22154152 A EP22154152 A EP 22154152A EP 4219812 A1 EP4219812 A1 EP 4219812A1
Authority
EP
European Patent Office
Prior art keywords
connecting rod
shed
warp
forming device
crank
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP22154152.7A
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German (de)
English (en)
Inventor
Johann Brandstätter
Herbert Fürst
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Starlinger and Co GmbH
Original Assignee
Starlinger and Co GmbH
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Starlinger and Co GmbH filed Critical Starlinger and Co GmbH
Priority to EP22154152.7A priority Critical patent/EP4219812A1/fr
Priority to TW112101447A priority patent/TW202346673A/zh
Priority to PCT/EP2023/051300 priority patent/WO2023144017A1/fr
Publication of EP4219812A1 publication Critical patent/EP4219812A1/fr
Withdrawn legal-status Critical Current

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Classifications

    • DTEXTILES; PAPER
    • D03WEAVING
    • D03DWOVEN FABRICS; METHODS OF WEAVING; LOOMS
    • D03D37/00Circular looms
    • DTEXTILES; PAPER
    • D03WEAVING
    • D03CSHEDDING MECHANISMS; PATTERN CARDS OR CHAINS; PUNCHING OF CARDS; DESIGNING PATTERNS
    • D03C5/00Cam or other direct-acting shedding mechanisms, i.e. operating heald frames without intervening power-supplying devices
    • D03C5/02Cam or other direct-acting shedding mechanisms, i.e. operating heald frames without intervening power-supplying devices operated by rotating cams

Definitions

  • the invention relates to a shed forming device of a circular loom, according to the preamble of claim 1, and a circular loom equipped therewith.
  • Circular weaving machines for producing fabrics are generally known from the prior art, which have a circular reed which is arranged coaxially to a main shaft of the circular weaving machine.
  • the main shaft forms a main axis of the circular loom.
  • warp ribbon guide elements Arranged around the circular reed are warp ribbon guide elements, which are designed to feed a large number of warp ribbons to the circular weaving machine.
  • Shed forming devices group the supplied warp bands into two warp bands and give them mutually opposite alternating movements, whereby a shed is opened and closed between the two warp bands.
  • a shuttle moves on an orbit in the open shed and thereby inserts a weft ribbon into the shed, as a result of which a fabric is formed.
  • several shuttles run around at the same time in a respective shed in the circular reed. The fabric is drawn off through a weaving ring.
  • the Austrian patent AT 385 060 describes a shaft drive designed as a crank mechanism for a circular weaving machine, in which the inner and outer partial shafts are arranged in a circle in two rows around the main shaft of the machine.
  • the partial shafts have eyelets for guiding warp ribbons.
  • One inner and one outer partial shaft each form a pair of partial shafts driven by a crank drive arrangement, with the crank drive arrangement imparting a lifting movement in opposite directions to the inner and outer partial shaft to form a shed.
  • a stepped weaving shed is created, also referred to below as a stepped shed.
  • the shedding drive is usually implemented with cams and control levers.
  • several shed-forming devices located next to one another are usually combined into groups, which are articulated simultaneously by one or two control levers become.
  • This creates a stepped shed which has the disadvantage that it is shortened in the end areas and, seen over the entire length, offers little space for the shuttle due to the smaller usable space.
  • a dead space between two successive sheds is increased by the stepped shape, which means that a smaller number of shuttles can run around the circular reed at the same time in such circular looms.
  • a small number of shuttles leads to a reduction in the production speed of the circular loom, thereby reducing the output of the circular loom.
  • the European patent application EP 3431643 A1 describes a shed forming device, by means of which the warp thread lifting means are set simultaneously in a lifting and a pivoting movement when the shed is opened, the pivoting movement taking place about an axis which is arranged radially to the main axis of the circular loom.
  • the sliding blocks of the cam are subject to considerable sliding friction, which represents a load limit for the circular loom at higher speeds.
  • the efficiency of a circular loom is essentially characterized by its production speed, the quality of the fabric formed and its energy consumption.
  • the upper limit of the production speed is determined by the maximum speed of the shed formation, or that of the shed change between the open and closed state of the shed, at which the shuttle can move in the traveling shed without colliding with the warp bands delimiting the shed.
  • the object of the present invention is to provide a shed forming device for forming a lenticular shed that offers more space for the shuttle compared to a stepped shed, and at the same time overcomes the disadvantages of a solution with additional pivoting elements in order to increase the production speed or the overall diameter of the circular loom.
  • the lens-shaped cross-section of the shed/sheds allows the number of shuttles running around the reed at the same time to be maximized, or the distance between the shuttles and the warp tapes at the ends of the shed/sheds can be increased with the same number of shuttles , which reduces the risk of the weaving shuttle colliding with the warp bands and avoiding the warp bands tearing as a result.
  • the rolling friction between the control cam and eccentric roller causes comparatively high energy consumption.
  • the present invention is based on the object of providing a more energy-saving circular weaving machine.
  • the present invention solves the stated objects by providing a shed forming device of a circular loom having the features of claim 1 and a circular loom having the features of claim 20.
  • Advantageous embodiments of the invention are set out in the dependent claims, the following description and the drawings.
  • the shed forming device has warp-bearing elements for guiding warp bands in two warp sheets, the warp-bearing elements imparting opposite alternating movements to the two warp sheets to form a shed.
  • the shed-forming device has a crank drive with a crank element, in particular a crankshaft or crank disk, and at least one connecting rod connected to the crank element.
  • the connecting rod comprises a longitudinal beam and a transverse beam, with a first connecting rod bearing being formed in the longitudinal beam, which is articulated on the crank element and the elements carrying warp ribbons are articulated on the transverse beam of the connecting rod, the connecting rod having a second connecting rod bearing which can be rotated and linearly displaced on a linear guide is guided.
  • the linear guide preferably has a guide carriage and a guide rod guiding the guide carriage, the second connecting rod bearing being articulated on the guide carriage.
  • the guide carriage sets the second connecting rod bearing in a lifting motion along the guide rod.
  • the guide carriage can, for example, be guided along the guide rod either with roller bearings or aerostatically or magnetically.
  • the second connecting rod bearing In order to minimize sideways movements of the elements carrying the warp ribbons arranged on the crossbeam, it is expedient for the second connecting rod bearing to be positioned in the middle of the crossbeam of the connecting rod.
  • the longitudinal beam and the transverse beam of the connecting rod are at such an angle to one another that when the first connecting rod bearing is at a top or bottom dead center, the transverse beam of the connecting rod is horizontal.
  • connecting rods having a longitudinal beam and a transverse beam are provided on the shed-forming device according to the invention, sideways movements of the elements carrying warp bands arranged on the transverse beam can be minimized. These sideways movements result from the circular movement of the crossbar when the connecting rod pivots and are greater the further away the elements carrying warp strips are from the second connecting rod bearing. If several connecting rods are provided, the crossbeams can be made correspondingly shorter, which reduces the sideways movements mentioned.
  • the connecting rods are fastened with their first connecting rod bearings to a common articulation point, in particular a common crank pin, of the crank element, with each of the connecting rods being guided in its own linear guide at its second connecting rod bearing.
  • At least one main connecting rod with a longitudinal bar and a transverse bar and a secondary connecting rod with a longitudinal bar and a transverse bar are provided, the main connecting rod being articulated with its first connecting rod bearing on the crank element, the longitudinal bar of the secondary connecting rod being attached to the longitudinal bar of the main connecting rod and the The main connecting rod and the secondary connecting rod are guided on their second connecting rod bearings, each in their own linear guide.
  • the elements carrying the warp bands are provided as eyelet bands looping around the deflection rollers or cords with warp band eyes formed in sections on both sides of the deflection rollers.
  • the shed-forming device according to the invention can be produced more easily and with fewer individual parts than conventional shed-forming devices, although an approximately lens-shaped shed formation is possible if the elements carrying the warp bands are looped around the deflection rollers as eyelets or cords with a first group of at least two warp-band eyes arranged next to one another and one second group of at least two juxtaposed warp eyes, the two groups of warp eyes being formed on sections of the eyelet tape or the cord on both sides of the deflection rollers.
  • the elements of a group that carry warp ribbons are each articulated together.
  • the warp-tape-carrying elements comprise machine tapes looping around the deflection rollers, into which heddles with hooks are hung at their ends, the heddles having warp-tape eyes.
  • the warp bands of the two warp bands can pass side by side when being fed to the shed without touching one another.
  • a simple fastening of the elements carrying the warp ribbons results when these elements are twisted and attached to the crossbar of the connecting rod, preferably clamped.
  • the connecting rod is not at half stroke height when its first connecting rod bearing is in the 9 o'clock or 3 o'clock position during operation of the crank drive, but is offset by a stroke error compared to half stroke height.
  • This causes alternately different distances at which the sheds are closed, also referred to as "closed shed".
  • the sheds are alternately longer and shorter. Therefore, if you want to use shuttles of the same length, you have to use the shorter sheds as a guide when selecting a shuttle length. Alternatively, one could alternately use longer and shorter shuttles. However, both measures do not achieve optimal results.
  • the invention therefore provides measures to form all sheds of the same length or to keep the closed states of all sheds at the same distances.
  • the shed-forming device with compensation means for compensating for system-related stroke errors of the connecting rods or elements carrying warp ribbons connected to the connecting rods.
  • the compensation means are designed as a gear mechanism with elliptical gears, preferably elliptical spur gears or bevel gears, which is connected upstream of the crank drive and drives the crank drive.
  • Gear drives with elliptical gears, such as spur or bevel gears have a periodically changing transmission ratio and thus, in combination with the crank drive, give the elements carrying the warp ribbons a uniform, almost sinusoidal lifting movement.
  • the elliptical gear mechanism consists of gears whose pitch curves are ellipses.
  • the fulcrums of the gears lie in one of the foci of the ellipse, which have the linear eccentricity with respect to their centers of the ellipse.
  • the magnitude of the eccentricity determines the gear ratio variation and is dependent on the crank ratio.
  • the compensation means are designed as an individual electric drive that drives the crank drive and carries out compensating movements. These individual drives can be controlled electronically so that they provide the required movement profile by means of a compensating movement.
  • the compensation means are designed as a separate drive train of the crank drive, the separate drive train having a drive shaft with a driver and a crankshaft with a driver stone, the axes of rotation of the drive shaft and the crankshaft being offset from one another by a correction distance.
  • the essential feature of this embodiment is that the axes of rotation of the drive shaft and the driven crankshaft have a parallel offset to one another and are positively connected only via a driver element.
  • the compensation means are designed as a cardan shaft which is connected upstream of the crank drive and drives the crank drive, with a deflection angle of the cardan shaft being adjusted in such a way that the resulting cardan error compensates for the stroke error.
  • the invention also includes a circular loom with a circular reed and with warp ribbon guide elements, which are arranged around the circular reed of the circular loom for feeding a large number of warp ribbons to the circular loom, with a plurality of weaving shuttles running around the circular reed for inserting weft ribbons into sheds formed by the warp ribbons and with a main drive for driving the shuttles, the circular loom comprising a large number of the shed-forming devices according to the invention defined above, which are arranged around the circular reed, with the shed-forming devices being driven directly or indirectly by the main drive.
  • crank elements of the shed-forming devices are preferably rotated via a toothed wheel connection that is operatively connected to the main drive, preferably a bevel gear connection, or via toothed belts that are operatively connected to the main drive.
  • FIG. 1A, 1B and 1C a first embodiment of the shed forming device 1 according to the invention of a circular loom is shown in front view, side view and from above.
  • the shed forming device 1 has a large number of elements 2 carrying warp bands for guiding warp bands 3, 4 in two groups of warp bands 3a, 4a, the elements 2 carrying warp bands imparting opposite alternating movements to the two groups of warp bands 3a, 4a to form a shed 5, each the elements 2 carrying the warp ribbons, two deflection rollers 6, 6 wraps around.
  • the elements 2 carrying the shackle can be formed, for example, as eyelets, cords or strands with sections formed on both sides of the deflection rollers 6 small warp eyes 2a.
  • the axes of rotation 6a of the deflection rollers 6 are inclined so that the warp bands 3, 4 of the two warp band sheets 3a, 4a pass side by side when being fed to the shed 5 without touching one another.
  • a shuttle (not shown) circulates in a circular reed 12 of a circular loom and releases the weft thread that it carries on a roll to the edge of the fabric being formed.
  • a large number of the shed forming devices 1 according to the invention are arranged around the circular reed 12 and are driven directly or indirectly by the main drive of the circular loom.
  • the crank elements 7 of the shed-forming devices 1 are expediently rotated via a toothed wheel connection which is operatively connected to the main drive, preferably a bevel gear connection, or via toothed belts which are operatively connected to the main drive.
  • Warp ribbon guide elements are arranged around the circular reed 12 of the circular loom for feeding a plurality of warp ribbons to the circular loom.
  • Several shuttles running around the circular reed 12 are provided for inserting weft ribbons into sheds 5 formed by the warp ribbons.
  • such circular looms are known to those skilled in the art and can, for example, in EP 3431643 A1 be executed as described.
  • the shed forming device 1 has a crank drive with a crank element 7, in particular a crankshaft or crank disk, and at least one connecting rod 8 connected to the crank element 7.
  • the crank element 7 is driven by a crank drive 13, which in this exemplary embodiment comprises a rotatably mounted drive shaft 13a and a bevel gear 13b which is non-rotatably connected to the drive shaft 13a and can be connected to a main drive of a circular loom (not shown).
  • the connecting rod comprises a longitudinal bar 8a and a transverse bar 8b, with a first connecting rod bearing 8c being formed in the longitudinal bar 8a, which is articulated on the crank element 7 at a crank pin 7a and the elements 2 carrying warp strips are articulated on the transverse bar 8b of the connecting rod 8,
  • the Connecting rod 8 has a second connecting rod bearing 8d, which is guided on a linear guide 9 in a rotatable and linearly displaceable manner.
  • the linear guide 9 comprises a guide carriage 10 and a guide rod 11 guiding the guide carriage 10 , the second connecting rod bearing 8d being articulated on the guide carriage 10 .
  • the guide carriage 10 is preferably guided either with roller bearings or aerostatically or magnetically along the guide rod 11 in order to have the lowest possible frictional resistance.
  • the second connecting rod bearing 8d is in the middle of the crossbeam 8b of the connecting rod 8 so that the same number of elements 2 carrying warp strips are arranged to the left and right of the second connecting rod bearing 8d.
  • the longitudinal beam 8a and the transverse beam 8b of the connecting rod 8 are at such an angle to one another that when the first connecting rod bearing 8c is at an upper (12 o'clock position) or lower (6 o'clock position) dead center of the crank element 7, the transverse beam 8b of the connecting rod 8 is horizontal. In the embodiment of Figures 1A-1C this angle between the longitudinal beam 8a and the transverse beam 8b is 90°.
  • the elements 2 carrying warp ribbons are articulated on the crossbeam 8b of the connecting rod 8 with articulations 8e, for example pins.
  • the rotary movement of the crank element is converted into a linear movement of the connecting rod 8 by the longitudinal beam 8a of the connecting rod 8 .
  • this only applies to the second connecting rod bearing 8d, which is articulated on the guide carriage 10.
  • the crossbar 8b of the connecting rod 8 also performs a pivoting movement about the second connecting rod bearing 8d.
  • This pivoting movement of the crossbar 8b leads to a certain back and forth sideways movement of the warp-carrying elements 2 arranged on the crossbar 8b, which is greater the further away from the second connecting rod bearing 8d (i.e. the pivot point) a warp-carrying element 2 on the crossbar 8b is arranged.
  • the distance between the mounting of an element 2 carrying warp ribbons on the crossbeam 8b and the second connecting rod bearing 8d defines the swivel radius.
  • the sideways movement described is undesirable and should therefore be minimized. This is achieved by keeping the length of the crossbar 8b small.
  • this length cannot be reduced arbitrarily, but depends geometrically on the number of elements 2 carrying warp ribbons and their distance from one another, the invention provides in further embodiments to increase the number of connecting rods, whereby the length of each crossbar 8b is kept short can be.
  • FIG. 2A and 2B an embodiment of the shed forming device 1 according to the invention is shown, on which a total of four connecting rods 8 are articulated on a crank element 7 .
  • Two connecting rods 8 are fastened with their first connecting rod bearings 8c directly or indirectly to a common articulation point, in particular a common crank pin 7a, of the crank element 7 and each of the connecting rods 8 is guided in its own linear guide 9 on its second connecting rod bearing 8d.
  • the crank element 7 is designed as a crank disk, the two crank pins 7a are offset from one another by 180° arranged with a crank pin 7a at the front and a crank pin 7a at the rear of the crank disk.
  • longitudinal beams 8a and transverse beams 8b of the connecting rod are arranged at angles other than 90° with respect to one another.
  • Direct attachment of a connecting rod 8 to the pivot point on the crank element 7 means that the first connecting rod bearing 8c is connected directly to the crank pin 7a.
  • Indirect attachment of a connecting rod 8 to the articulation point on the crank element 7 means that there is a main connecting rod 8 with a longitudinal beam 8a and a transverse beam 8b, which is articulated with its first connecting rod bearing 8c directly on the crank element 7 (direct connection), and that there is also a secondary connecting rod 8' with a longitudinal bar 8a and a transverse bar 8b, the longitudinal bar 8a of the secondary connecting rod 8' being attached to a secondary connecting rod articulation point 8f of the longitudinal bar 8a of the main connecting rod 8 and the main connecting rod 8 and the secondary connecting rod 8' being attached to their second Connecting rod bearings 8d are each guided in their own linear guide 9.
  • the secondary connecting rod 8' is thus only indirectly connected to the crank element 7 and is carried along by the main connecting rod 8.
  • the secondary connecting rod 8' can be omitted, leaving only the main connecting rod 8.
  • connecting rods 8 are provided, with the first connecting rod bearing 8c of each connecting rod 8 at its own articulation point, here its own crank pin 7a, is mounted on the crank element 7, and each of the pivot points on the crank element 7 is offset from its adjacent pivot points by 360°/N and each connecting rod 8 is guided in its own linear guide 9.
  • the shed formation facilities 1 are characterized in that the elements 2 carrying warp ribbons are designed as separate elements, each of which is articulated individually on a crossbar 8b of a connecting rod 8. This results in a perfectly lens-shaped shed 5.
  • the elements 2 carrying warp ribbons are provided as eyelets or cords looping around the deflection rollers 6 with warp ribbon eyes 2a formed in sections on both sides of the deflection rollers, run from the shed forming device 1 Figures 2A-2B the elements 2 carrying warp ribbons do not revolve around deflection rollers, but are attached with one end to the linkages 8e of the crossbeam 8b of the connecting rod 8 and with a second end to attachment points 14a of a holding beam 14, the dimensions of which correspond to the crossbeam 8b of the connecting rod 8 .
  • the attachment points 14a are equidistant from each other arranged like the articulations 8e of the transom 8b of the connecting rod.
  • the support beam 14 can be pivoted about a support beam bearing 14b, which is seated at one end of a spacer 15, which is designed, for example, as a rod or tube.
  • the spacer 15 is also connected to the guide carriage 10 of the linear guide 9 and is carried along by the connecting rod 8 along the linear guide 9, so that the distance between the crossbar 8b of the connecting rod 8and the retaining bar always remains constant.
  • the pivoting of the crossbeam 8b is transmitted through the elements 2 carrying warp ribbons to the retaining beam 14, which is thus pivoted parallel to the crossbeam 8b of the connecting rod 8.
  • the embodiment of the shed-forming device 1 shown schematically in a front view or side view comprises the elements 2 carrying the warp bands, the machine bands 16 looping around the deflection rollers 6 and into which the strands 17 with hooks 17a are hung at their ends.
  • the warp-tape-carrying elements 2 are formed as tapes into which the warp-tape eyes 2a are incorporated, the tapes being passed around the deflection rollers 6, 6 and joined together at a joint 2b to form an endless tape. Furthermore, the bands are twisted by 180° (at 2c) and are fastened in the region of their twisting to clamping points 8g of the crossbeam 8b of the connecting rod 8 by means of clamping.
  • the invention provides compensation means in order to form all sheds 5 of the same length or to keep the closed states of all sheds 5 at the same distances.
  • the compensation means are designed as a gear train 19 with elliptical gear wheels 19a, 19b which is connected upstream of the crank drive 13 and drives the crank drive 13.
  • the elliptical gears 19a, 19b are designed as elliptical bevel gears. Alternatively, they could also be designed as elliptical spur gears, with the pitch curves being ellipses in both types of gears.
  • Gear drives 19 with elliptical gears have a periodically changing transmission ratio and thus, in combination with the crank drive 13, give the elements 2 carrying the warp ribbons a uniform, almost sinusoidal lifting movement.
  • the pivot points of the elliptical gears 19a, 19b lie in one of the foci of the ellipse, which have the linear eccentricity with respect to their centers of the ellipse.
  • the magnitude of the eccentricity determines the gear ratio variation and is dependent on the crank ratio.
  • the bevel gear 19a is driven by an intermediate shaft 20, which in turn is driven via a gear train 21 by the main shaft 18 of the circular loom.
  • the compensation means are designed as a separate drive train of the crank drive 13, with the separate drive train having an eccentric drive shaft S1 with a driver C1 and a crankshaft S2 with a driver block C2, with the axes of rotation of the drive shaft S1 and the crankshaft S2 being parallel are offset from each other by a correction distance K from each other.
  • the essential feature of this embodiment is that the axes of rotation of the drive shaft S1 and the driven crankshaft S2 have a parallel offset to one another and are positively connected only via the driver elements C1, C2.
  • the drive shaft S1 is driven by the main shaft of the circular loom, e.g.
  • the crank drive 13 of the crank element 7 is non-positively connected to the crankshaft C2 and therefore executes the lifting movement of the connecting rod 8 in such a way that at 90° (9 o'clock) and 270° (3 o'clock) the connecting rod 8 is exactly in the middle position between top dead center TDC (at 0° or 12 o'clock) and the bottom dead center UT (at 180° or 6 o'clock).
  • the distance between the top dead center OT and the bottom dead center UT is the lift height H, the center position of the connecting rod 8 is thus at half the lift height H/2.
  • the compensation means are designed as an individual electric drive that drives the crank drive and performs compensating movements. These individual drives can be controlled electronically so that they provide the required movement profile by means of a compensating movement.
  • the compensation means are designed as a cardan shaft upstream of the crank drive and driving the crank drive, with a deflection angle of the cardan shaft being set such that the resulting cardan error compensates for the stroke error.

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  • Engineering & Computer Science (AREA)
  • Textile Engineering (AREA)
  • Looms (AREA)
EP22154152.7A 2022-01-31 2022-01-31 Dispositif de formation de la foule d'un métier circulaire et métier circulaire équipé d'un tel dispositif Withdrawn EP4219812A1 (fr)

Priority Applications (3)

Application Number Priority Date Filing Date Title
EP22154152.7A EP4219812A1 (fr) 2022-01-31 2022-01-31 Dispositif de formation de la foule d'un métier circulaire et métier circulaire équipé d'un tel dispositif
TW112101447A TW202346673A (zh) 2022-01-31 2023-01-12 圓織機的編織梭口形成裝置以及設有編織梭口形成裝置的圓織機
PCT/EP2023/051300 WO2023144017A1 (fr) 2022-01-31 2023-01-19 Dispositif de formation de foule d'un métier à tisser circulaire, et métier à tisser circulaire équipé de celui-ci

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
EP22154152.7A EP4219812A1 (fr) 2022-01-31 2022-01-31 Dispositif de formation de la foule d'un métier circulaire et métier circulaire équipé d'un tel dispositif

Publications (1)

Publication Number Publication Date
EP4219812A1 true EP4219812A1 (fr) 2023-08-02

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EP22154152.7A Withdrawn EP4219812A1 (fr) 2022-01-31 2022-01-31 Dispositif de formation de la foule d'un métier circulaire et métier circulaire équipé d'un tel dispositif

Country Status (3)

Country Link
EP (1) EP4219812A1 (fr)
TW (1) TW202346673A (fr)
WO (1) WO2023144017A1 (fr)

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2811986A (en) * 1952-11-28 1957-11-05 Sagem Loom
US4694866A (en) * 1986-05-05 1987-09-22 Kuo Ching Huang Shedding device for a circular weaving machine
AT385060B (de) 1980-07-09 1988-02-10 Setafin Sa Schaftantrieb an einer rundwebmaschine
EP3431643A1 (fr) 2017-07-21 2019-01-23 Starlinger & Co Gesellschaft m.b.H. Métier à tisser circulaire

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2811986A (en) * 1952-11-28 1957-11-05 Sagem Loom
AT385060B (de) 1980-07-09 1988-02-10 Setafin Sa Schaftantrieb an einer rundwebmaschine
US4694866A (en) * 1986-05-05 1987-09-22 Kuo Ching Huang Shedding device for a circular weaving machine
EP3431643A1 (fr) 2017-07-21 2019-01-23 Starlinger & Co Gesellschaft m.b.H. Métier à tisser circulaire

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WO2023144017A1 (fr) 2023-08-03
TW202346673A (zh) 2023-12-01

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