EP0584432A1 - Weaving rotor for a linear-shed multiphase loom - Google Patents

Abstract

The invention shows, for a linear-shed multi-phase loom, weaving rotors with relay nozzles (3) which are fed with compressed air within the weaving rotor by means of an air-distributing system (10) via transfer stations distributed in the axial direction, in order to generate a travelling wave (22) in relation to the weaving rotor. At the same time, the transfer stations (6), which each feed a group (31) of relay nozzles (3) via a supply channel (11), are mounted adjustably in the direction of rotation (41) and are connected to an adjusting device (27, 33), via which the rotary angle (8) between the transfer orifices (7) of different transfer stations (6) is adjustable on the wide side (72, 73) of the weaving rotor (1). This, even with a reduced weaving width (36), makes it possible to utilise the maximum possible weft-insertion angle alpha along with the highest possible weft-insertion speed. <IMAGE>

Description

The invention relates to a weaving rotor for a row shed weaving machine, in which relay nozzles are installed along the weft channels and can be actuated with air pulses. A stationary and constantly pressurized air distribution system is installed inside the weaving rotor, which has transfer stations distributed on axis sections along the rotor axis. the transfer openings of which are offset from one another by an angle of rotation and the air in supply openings rotating relative to them feed air into supply channels for relay nozzles during the covering of the cross sections in order to generate a traveling field relative to the weaving rotor.

Such a weaving rotor is shown in patent specification EP 0 143 859. A fixed switch tube with openings in the outer surface is close to the inside of the cylinder surface of a weaving rotor and feeds air into rotating holes in the cylinder jacket. The openings in the switching tube lie on a helical line so that a traveling field is generated via the holes assigned to a row of combs, to which relay nozzles are connected. A disadvantage of this arrangement is that the traveling field is predetermined by the geometry of the switching tube. The maximum of the weft entry possible entry speed can only be used with a certain weaving width. If the weaving width is smaller than this, there will be unused pauses between the individual weft stops at the maximum possible entry speed. The invention provides a remedy here.

The object of the invention is to use a certain weft insertion speed, which is provided for a maximum weaving width, even with smaller weaving widths, in that the shortening of the weft insertion leads to a corresponding shortening of the weaving cycle. According to the invention, the object is achieved by the features of independent claim 1.

The advantages of the invention can be seen in the fact that the total rotation angle available for the weft insertion can be set independently of the weaving width for a specific weft insertion speed. Furthermore, it is possible to optimize the blowing pressure and the helix of the transfer openings from the outside while the row shed weaving machine is running. At the transfer stations, there are only low frictional forces that are independent of the blowing pressure of the relay nozzles, which, due to the low heat generation, also allow heat-insulating and light materials such as relatively cheap plastics as wear-resistant sliding partners. The dependent subclaims 2 to 17 relate to advantageous developments of the invention.

Fig. 1a

schematisch wie für den Schusseintragswinkel α als Abwicklung eines Webrotors ein Wanderfeld über die Webbreite erzeugt wird, wobei die Ueberdeckung von Uebergabeöffnungen durch Uebernahmeöffnungen schematisch überlagert ist;

Fig. 1b

schematisch einen zu Fig. 1a passenden Webrotor mit Uebergabestationen und Stafettendüsen zu einem Schusskanal;

Fig. 2a

schematisch als Abwicklung ein Wanderfeld für den gleichen Drehwinkel wie in Fig. 1a jedoch mit einer um die Wirkung einer Uebergabestation gekürzten Webbreite;

Fig. 2b

schematisch den zu Fig. 2a passenden Webrotor bei dem der Schusskanal auf eine kleinere Webbreite verkürzt wurde;

Fig. 3

schematisch einen Schnitt längs der Rotationsachse eines Webrotors mit einer doppelt ausgeführten Uebergabestation;

Fig. 4

schematisch einen Schnitt längs der Rotationsachse eines Webrotors, aus dem die Lagerung an einer Breitseite des Webrotors und eine Verstelleinrichtung für Uebergabestationen ersichtlich ist;

Fig. 5

schematisch auseinandergeklappt eine stationäre Uebergabeöffnung und mit dem Webrotor daran vorbeidrehende Uebernahmeöffnungen;

Fig. 6

schematisch einen Schnitt VI in Figur 3 quer zur Rotationsachse, aus dem die Verteilung der Druckluft von den Uebernahmeöffnungen zu den Stafettendüsengruppen der verschiedenen Schusskanäle ersichtlich ist;

Fig. 7

schematisch einen unterbrochenen Schnitt VII in Figur 3 quer zur Rotationsachse durch eine Uebergabestation;

Fig. 8

schematisch die vergrösserte Ansicht einer stationären Uebergabeöffnung gemäss Figur 5 mit der in der Trennebene zu den Uebernahmeöffnungen wirksamen Dichtfläche und der dahinter liegenden Gegenfläche;

Fig. 9

schematisch einen Schnitt IX durch die Uebergabeöffnung in Figur 8, aus dem der Kräfteausgleich zwischen Dichtfläche und Gegenfläche ersichtlich ist;

Fig. 10

schematisch einen Ausschnitt aus einer Streckeinrichtung an der Schussaustrittseite, bei der injektorähnliche Streckdüsen, die jeweils quer zum Schusskanal auf einem Ring mit dem Webrotor mitrotieren, von einer stationären Lufteinspeisung mit Druckluft versorgt werden, und

Fig. 11

schematisch einen Schnitt längs der Rotorachse eines Webrotors durch eine axial verschiebbare Streckeinrichtung, bei der sich die stationäre Lufteinspeisung über einen doppelten, federverspannten Ring axial zwischen zwei drehenden Ringen zentriert.

The invention is described below using exemplary embodiments. Show it:

Fig. 1a

schematically as for the weft insertion angle α as a winding of a weaving rotor a traveling field is generated over the weaving width, the Coverage of transfer openings by transfer openings is schematically superimposed;

Fig. 1b

schematically a weaving rotor suitable for FIG. 1a with transfer stations and relay nozzles to form a weft channel;

Fig. 2a

schematically as a development a traveling field for the same angle of rotation as in FIG. 1a, but with a weaving width reduced by the effect of a transfer station;

Fig. 2b

schematically the weaving rotor matching FIG. 2a in which the weft channel has been shortened to a smaller weaving width;

Fig. 3

schematically shows a section along the axis of rotation of a weaving rotor with a double transfer station;

Fig. 4

schematically shows a section along the axis of rotation of a weaving rotor, from which the bearing on a broad side of the weaving rotor and an adjustment device for transfer stations can be seen;

Fig. 5

schematically unfolded a stationary transfer opening and transfer openings rotating past it with the weaving rotor;

Fig. 6

schematically a section VI in Figure 3 transverse to the axis of rotation, from which the distribution of the compressed air from the take-over openings to the relay nozzle groups of the different shot channels can be seen;

Fig. 7

schematically an interrupted section VII in Figure 3 transverse to the axis of rotation through a transfer station;

Fig. 8

schematically shows the enlarged view of a stationary transfer opening according to Figure 5 with the sealing surface effective in the parting plane to the transfer openings and the counter surface behind it;

Fig. 9

schematically a section IX through the transfer opening in Figure 8, from which the balance of forces between the sealing surface and the counter surface can be seen;

Fig. 10

schematically shows a section of a stretching device on the weft exit side, in which injector-like stretching nozzles, each rotating along the ring with the weaving rotor on the ring, are supplied with compressed air from a stationary air feed, and

Fig. 11

schematically shows a section along the rotor axis of a weaving rotor through an axially displaceable stretching device, in which the stationary air feed is axially centered between two rotating rings via a double, spring-loaded ring.

For a row shed weaving machine, the figures show weaving rotors with relay nozzles, which are fed with compressed air within the weaving rotor by an air distribution system via transfer stations distributed in the axial direction in order to generate a traveling field relative to the weaving rotor. The transfer stations, each feeding a group of relay nozzles via a feed channel, are in The direction of rotation is adjustable and is connected to an adjusting device, by means of which the angle of rotation between the transfer openings of different transfer stations on the broad side of the weaving rotor can be adjusted. This enables the maximum possible weft insertion angle to be used at the highest possible weft insertion speed even with a reduced weaving width.

In FIG. 1a, a hatched traveling field 22 is plotted over the weaving width 36 for a weaving rotor 1 and depending on the weft insertion angle α developed for a weft channel 2 of the weaving rotor. In the same representation, transfer openings 7 and transfer openings 17 are projected which, when covered, each supply air to a group 31 of relay nozzles 3 in the double-hatched area of the traveling field for axis sections 4. The weaving rotor 1 is shown schematically in section across the weaving width 36 in FIG. 1a in FIG. 1b. The weaving rotor 1 is equipped along its weft channels 2 with relay nozzles 3, which are combined in groups 31. Each group 31 is supplied with compressed air on the inside of the weaving rotor by an associated transfer station 6, all transfer stations being part of an air distribution system 10 which is under constant pressure. The transfer stations 6 are rotatably mounted within the weaving rotor 1 and can be adjusted in the direction of rotation via an adjusting device 33 on the broad side 73 and / or an adjusting device 27 (not shown here) on the opposite broad side 72. In this case, the transfer stations 6 are supported by suitable torsion spring sections 9 in the direction of rotation against one another and to the broad sides 72, 73, and the air distribution system 10 connects the individual transfer stations 6 with hoses that are movable in the direction of rotation, a connecting hose being led out of the hollow weaving rotor 1 rotating in rotor bearings 67 is. One formed in a row of combs 37 Weft channel 2 is interrupted at the end of weaving width 36 by a cutting gap 34, in which there is a cutting device 12 which limits the stretched weft thread to the final length. The weft thread is stretched with a stretching device 13 located behind it, which generates a stretching field 35 shown in FIG. 1a. The transfer stations 6 have, for each group 31 of the relay nozzles, a transfer opening 7 distorted in the direction of rotation, via which air is blown into transfer openings 17 of the weaving rotor 1 rotating past. The blowing duration of the relay nozzles 3 is determined via a blowing angle 69, which corresponds to the distortion of the transfer opening 7 in the direction of rotation. The transfer openings 7 of two adjacent transfer stations 6 are offset from one another by an angle of rotation 8 in the direction of rotation. With the adjusting devices 27, 33, the angle of rotation 8 between two adjacent transfer stations can be changed and the total gradient of the traveling field 22 can be adapted to a new weaving width 36 in order to be able to keep the weft insertion angle α constant regardless of the weaving width. This has the advantage that the weaving rotor 1 with small weaving widths 36 can use the largest possible weft insertion angle α and can rotate faster in order to increase the number of wefts.

In FIGS. 2a, b, the weaving width 36 was shortened for an embodiment corresponding to FIGS. 1a, b by removing the associated combs 37 of the outermost transfer station 6 from the weaving rotor 1 and the stretching device 13 and the cutting device 12 by the corresponding amount in the direction of Rotor axis were moved inwards. The associated takeover opening 68 is blinded. The original weft insertion angle α is achieved by increasing the angle of rotation 8 between the adjacent transfer stations which are adjustable in the direction of rotation. In the case of adjustment via torsion spring sections 9 an adjustment of the outermost torsion spring section in the direction of rotation is carried out on the adjusting device 33 and a greater torque is generated. In accordance with the increase in torque and the spring constants of the torsion spring sections 9, the angle of rotation 8 between adjacent transfer stations 6 increases. This rotation maintains the weft insertion angle and evenly divides the reduction in overlap between the groups 31 of relay nozzles involved.

Regardless of the type of adjustment for the transfer stations 6, these must be secured against unwanted twisting by means of mechanical supports on the broad sides 72, 73. Fluctuations in the friction in the separating surfaces between transfer opening 7 and transfer openings 17 act as disturbing variables on the angle of rotation 8. Furthermore, 6 heat and power loss are generated with a variety of transfer stations, which should be kept as low as possible. FIG. 5 shows a preferred arrangement for the takeover openings 17 of a transfer station 6, which lie on a circle 38 in a parting plane 18 which is perpendicular to the rotor axis 5 of the weaving rotor 1. The take-over openings 17 lie in the end face of a rotating ring body 48, which rotates connected to the weaving rotor. The transfer opening 7 distorted in the direction of rotation 41 lies in a stationary ring 47, which is designed as a slip ring and bears against the rotating ring body 48 under slight pressure. For the duration of the covering of transfer and take-over openings, an air flow 16 arises which leads from a bore 92 via the parting plane 18 into the feed channel 11 to a group 31 of relay nozzles 3. The stationary ring 47 is provided on its rear side with bores 46 which are intended for compression springs 44 and a pin provided as a rotation lock 30. Compensate the contact springs the position - tolerances in the end face of the rotating ring body 48.

In order to reduce the friction between the rotating ring body 48 and the stationary ring 47, it would be advantageous to make the contact springs as weak as possible. This is countered by the uneven pressure distribution on the end face of the stationary ring 47. The pressure in the sealing gap 19 along the transfer opening 7 is significantly higher than in other areas of the end face and tries to tilt the stationary ring 47. Since this pressure can vary with the machine setting, a different spring support is only effective to a limited extent. FIGS. 8 and 9 show a compensation of the pressure-dependent opening force 23, which acts on the stationary ring 47 in an effective sealing surface 25 by the same pressure generating a closing force 24 on a counter surface 26, which corresponds approximately to the amount of the opening force 23. The counter surface 26 is incorporated as the end face of a cylinder bore 59 from the rear of the stationary ring 47, a piston 49 protruding from a carrier body 20 with a soft seal 50 sealing against the blowing pressure on the cylindrical outer surface and permitting axial displacements of the stationary ring 47. The blowing air passes through a bore 21 in the piston 49 and through a bore 92 into the transfer opening 7. The blowing angle 69 is determined by the distortion of the transfer opening on the circle 38. FIG. 3 shows a double-acting transfer station 6, in which an axially displaceable stationary ring 47 is held on the left and right by a carrier body 20 via pressure springs 44 and rotation lock 30. The relay nozzle group is divided into a left and a right area, each of which is supplied with air by a piston 49. The two pistons 49 with the transfer openings 7 are offset from one another in the direction of rotation by a fixed amount and also form an intermediate level in the hiking field. Each of the two stationary rings 47 has a balance of the pressure-dependent opening force 23 and closing force 24.

FIGS. 3, 4, 6, 7 show a weaving rotor which has an air distribution system 10 with a tube 15 mounted concentrically in the weaving rotor. The transfer stations 6 are rotatably supported with their carrier body 20 on the tube 15, which is supported on the rotating ring body 48 for better guidance via bearings 42 with attachment 65. The ring bodies 48 rotating with the weaving rotor have a take-over opening 17 for each row of combs with a firing channel 2, followed by a feed channel 11 and a transition piece 39 to the relay nozzles 3, which at the same time seals and connects the rotating ring body 48 against the weaving rotor. The carrier body 20 is sealed against the tube 15 with two O-rings 70, which include a slot 57 in the tube 15 between them, and is displaceable in the direction of rotation.

The torsion spring sections 9 are combined in a torsion bar 29 which is arranged concentrically in the tube 15 and has a square cross section. The twist of the torsion bar 29 is transmitted at each transfer station by a rider 54, which is fastened on the torsion bar with a clamping screw 56 without play, via a driver screw 55 to the carrier body 20. The slot 57 in the tube 15 is dimensioned so large that a desired adjustment range can be traversed in the direction of rotation and that there is sufficient free cross section from the tube 15 as an air passage to an annular groove between the O-rings 70 to the holes 21 in the Feed piston 49. The riders 54 are dimensioned such that they can be rotated in the tube 15 and that they leave enough free cross-section in the axial direction for the air passage.

In order to have adjusting devices 27, 33 only on one broad side 73, the tube 15 and the torsion bar 29 are connected to one another in a rotationally fixed manner on the other broad side 72 within the weaving rotor 1. Figure 3 shows this connection via a coupling piece 58, which is supported by a bearing 51 in the weaving rotor 1 and which seals the tube 15 at its end with an O-ring 53 and a locking screw 88 airtight. The actual rotationally fixed connection takes place via a pin 52. A soft seal 50 and a bearing lock 43 are shown for the bearing 51. The tube 15, which is substantially more torsionally rigid than the torsion bar 29, serves as a mechanical transmission in order to transmit a twisting movement from a first adjusting device 27 on the broad side 73, as shown in FIG. 4, via an intermediate piece 32, while a further twisting movement on the same broad side 73 is carried out via a second adjusting device 33 at the other end of the torsion bar 29. Both adjusting devices 27, 33 and tube 15 with intermediate piece 32 are fastened to the housing 28 via a sleeve 90. Independently of this, the weaving rotor 1 is supported in the housing 28 via a rotor bearing 67. O-rings 76 and a soft seal 60 ensure that compressed air is brought into the pipe 15 via the connection opening 66 without leakage and that the leakage air is collected from the transfer stations 6 within the weaving rotor 1 and guided to the outside via bores 89 and outlet opening 45. The first adjusting device 27 consists of a clamping flange 61 which is tightened by the intermediate piece 32 after the rotation. In the second adjustment device 33, the rotation is carried out on the torsion bar 29 via the screw 62 and the screw edge 63 and is then secured with a clamping flange 64. The necessary screw connections are labeled 65.

An axially adjustable stretching device 13 is shown in FIGS. 10 and 11. A ring 74 co-rotating with the weaving rotor 1 and axially displaceable is at a distance from the cutting gap 34 on the weaving rotor with fastening elements 87 e.g. Locking screws secured. The weft channels 2 interrupted by the cutting gap 34 are continued in this ring 74, the ring 74 having an injector-like extension nozzle 71, which is interrupted transversely to each weft channel 2 and which deflects the weft thread tip while maintaining a stretching force transversely to the weft channel and the weft thread 40 in front the insertion into a cutting device and blows the cut weft tip through a nozzle half designed as a pull-off channel 78 into a stationary collecting device 77. On the side facing away from the cutting gap 34, the ring 74 has an end face which is perpendicular to the rotor axis and in which an oblique bore 82 with a takeover opening 80 ends for each stretching nozzle 71. The take-over openings 80 are at the same distance from the rotor axis 5 and are fed with compressed air for the duration of the overlap by a stationary air feed 79 via a transfer opening 75 distorted in the direction of rotation 41. Such a stretching device 13 is also useful without a cutting device 12 in order to stretch the weft 40 before it strikes the fabric, in which case a cutting gap 34 can then be dispensed with.

FIG. 11 shows an embodiment in which the stationary air feed 79 takes place via a compressed air connection 81 on a first race, which is braced with a second race via coil springs 85 to form a pair of rings 83 between the ring 74 and a counter ring 84 fastened thereon. Air feed 79 and the pair of rings 83 are prevented from rotating via an axially adjustable support arm 91 (see FIG. 2 b) connected to the housing 28 secured. This arrangement with the pair of rings 83 has the advantage, as with the transfer stations 6, that the high-quality sliding surfaces, which have transfer and transfer openings, are covered by a counter surface of the same size in order to keep the risk of contamination and wear small. A wedge for dirt particles can only arise at the transfer and take-over openings themselves, but this does not promote wear, since the latter is only flowed through by conditioned and pressurized air.

The pressure-independent balancing of forces at the transfer stations 6 and the low risk of contamination allow plastic to be used as a material for slide rings.

Claims (17)

Weaving rotor for a row shed weaving machine, in which relay wafers (3) are installed along the weft channels (2) and can be controlled with air pulses, a stationary and constantly pressurized air distribution system (10) being installed within the weaving rotor (1) (4) has transfer stations (6) distributed along the rotor axis (5), the transfer openings (7) of which are offset from one another by an angle of rotation (8) and the air in supply passages (11) for relay nozzles (17) rotating past them in relation to them. 3) feed in during the covering of the cross sections in order to generate a moving field (22) relative to the weaving rotor, characterized in that the transfer stations (6) are each connected to at least one group (31) of relay nozzles (3) via a feed channel (11) are that the transfer stations (6) within the weaving rotor (1) are adjustable in the direction of rotation and that the angle of rotation is adjusted (8) between the transfer openings (7) of different transfer stations (6) via adjusting elements (27, 33) on one or both of the broad sides (72, 73) of the weaving rotor. Weaving rotor according to claim 1, characterized in that the air distribution system (10) has a tube (15) which is mounted concentrically in the weaving rotor, on which the transfer stations (6) are rotatably mounted and from which the transfer stations (6) also during the adjustment of the angle of rotation ( 8) air can be fed to one another via slots (57) running in the direction of rotation (41). Weaving rotor according to claim 1 or 2, characterized in that the transfer stations (6) are connected to one another across the width of the weaving rotor (1) by torsion spring sections (9) which are attached by applying a torque or by rotating the support of the torsion spring sections (9) the broad sides (72, 73) of the weaving rotor cause a change in the angle of rotation (8) between the transfer openings (7) of different transfer stations (6). Weaving rotor according to claim 3, characterized in that the torsion spring sections (9) are connected to a continuous torsion bar (29) which is mounted concentrically in the weaving rotor and to which the transfer stations (6) are firmly connected with respect to rotation. Weaving rotor according to claim 4, characterized in that the tube (15) of the air distribution system (10) and the torsion bar (29) on the one broad side (72) of the weaving rotor (1) are rigidly connected to one another and on the other broad side (73) of the Weaving rotors can be rotated relative to one another by an adjusting device (33). Weaving rotor according to one of claims 1 to 5, characterized in that the transfer openings (7) to the relay nozzle groups (31) and the transfer openings (17) of the feed channels (11) lie in a parting plane (18) which is perpendicular to the rotor axis (5) touch and temporarily overlap while the weaving rotor is rotating. Weaving rotor according to claim 6, characterized in that in each case two relay nozzle groups (31) can be fed from a transfer station (6), the Transfer openings (7) are offset from one another by an angle of rotation (8) which corresponds to the mean offset in the direction of rotation for a traveling field between these two relay nozzle groups. Weaving rotor according to claim 6 or 7, characterized in that the transfer opening (7) and the transfer openings (17) assigned to each row of combs (37) lie on a common circle (38) in the parting plane (18), and in that the transfer opening (7) occupies a larger angular range than a takeover opening (17) on this circle (38). Weaving rotor according to one of claims 1 to 8, characterized in that the transfer opening (7) is movably mounted against the transfer openings (17) and pressed under spring force. Weaving rotor according to one of claims 6 to 9, characterized in that an opening force (23) which is dependent on the distribution pressure (21) in the sealing gap (19) between the transfer opening and the acceptance opening (7, 17) has a closing force (24) which is also dependent on the distribution pressure (21) ) counteracts by the distribution pressure acting on a counter surface (26) on the carrier body (20) of the transfer opening (7). Weaving rotor according to claim 10, characterized in that the sum of the opening forces (23) generated in the sealing gap by distributing pressure and effective sealing surface (25) and the sum of the closing forces (24) generated on the counter surface (26) is the same. Weaving rotor according to claim 11, characterized in that the counter surface (26) is the surface which minus the cross section of the transfer opening (7) a cylinder / piston seal between the transfer station (6) and the carrier body (20) is enclosed. Weaving rotor according to one of claims 1 to 5, characterized in that sections of the weft channels with the associated relay nozzles (3) are removably fastened on the exit side of the weft threads from the row compartment and that the feed channels (11) for the dismantled relay nozzles can be closed in order to to use remaining transfer stations (6) with a larger rotation angle distance (8) for a smaller weaving width (36). Weaving rotor according to one of claims 1 to 13, characterized in that the weaving rotor on the weft exit side has a stretching device (13) for the weft thread tips, which consists of a ring (74) which rotates with the weaving rotor (1) and which has a crosswise to each weft channel has an injector-like stretching nozzle (71) interrupted by the firing channel, and which has a stationary air feed (79) with a transfer opening (75) which, in the same way as the opening (80) of the ring (74) rotating in the same direction, rotates compressed air to the associated injector-like stretching nozzle ( 71) feeds. Weaving rotor according to claim 14, characterized in that there is a cutting gap (34) in front of the stretching nozzles (71) transversely to the weft channels for the installation of a stationary cutting device (12) in order to separate the weft thread tips of the stretched weft threads (40) and with the stretching nozzles ( 71) to blow into a collecting device (77). Weaving rotor according to claim 14, characterized in that the ring (74) rotating with the weaving rotor and the stationary air feed (79) are axially displaceable on the weaving rotor in order to fulfill their function with different weaving widths. Weaving rotor according to claim 14, characterized in that the stationary air feed (79) consists of a pair of rings (83) caught by the co-rotating ring (74) and a counter ring (84), which rests on the co-rotating ring (74, 84) with force compensation.

Images