TWI323750B - Ribbon needleloom - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a webbing machine according to the first aspect of the patent application, which has a heald device forming a shed. [Prior Art] A webbing machine having a heald device forming a shed as described in the foregoing is known. The heald device has a heald frame. However, its problem is that it is not stable enough when it is large in size and/or when the speed of the webbing machine is high. These spindles tend to flex and do not ensure a sufficient force transfer between the spindles. This may even result in damage to the heald frame. SUMMARY OF THE INVENTION The object of the present invention is to improve a webbing machine of the kind described in the introduction. The tasks mentioned above can be resolved by the features described in the scope of the patent application. Therefore, the heald frame has at least one heald support seat having a hollow rod having an upper inlet opening for the upper rail and a side inlet opening for the lower rail In this way, such a heald support can be used as a reinforcement for the heald frame at any I position. The key rails on the upper edge are coupled via a pressure bar disposed in the idling, and the wire is locked to the one end of the rod and the clamping bolts coaxially disposed on the pressure rod are locked to each other. Thereby, an important reinforcing effect can be produced on the green frame, which makes it possible to face a larger size on one hand and/or a higher rotational speed on the other. However, such a heald support can also be applied to the basic structure of the heald frame, that is, on the side thereof, the heald support can be applied to the upper and lower rails. The advantageous design of the webbing machine is described in item 2 of the scope of the patent application. According to the second aspect of the patent application, at least the inlet opening has a support flange of 6 1323750 laterally directed to the hollow rod, and the support manner of the spindle rail is improved. The hollow rod can be made of a single material. However, the more advantageous design is that according to the third aspect of the patent application, the hollow rod has a plurality of mutually staggered slots distributed over its entire length on its opposite sides, whereby the motion quality produces a significant Reduction. According to the fourth aspect of the patent application, the design is also the same. According to the design, the hollow rod is composed of a fiber-reinforced slidable plastic material, which can save a lot of cost. Further designs and advantages of this webbing machine are included in the special description of the embodiments below. BRIEF DESCRIPTION OF THE DRAWINGS The embodiment of the webbing machine according to the present invention is described in detail below based on the drawings. The drawings are as follows: Fig. - side view of a webbing machine; Fig. 2: a pneumatic pullback device The heald device is a view of the transverse movement of the warp, and the cross-sectional view of the heald frame with the heald support and the vertical cut; Figure 4: The flip of the cam drive of the heald device Above view of the rod; sectional view of the heald frame of one of the five-piece/spring pull-back device; Figure 6/heald frame with webbing, parallel to the vertical section view of the warp threads; Figure VII -VII sectional view; ^ Figure 8 is a schematic view of the side view of the belt machine; Figure 9 shows the plan layout of the transmission in Fig. 8; Fig. 10 is a top view of the weaving range of the webbing machine; Fig. 10 to Fig. 10 shows the XI-XI section of the weaving range Figure 12 is a schematic view of the wire feeding device of the webbing machine; 7 Figure XIII is a cross-sectional view of the wire weaving device of XII-XIII; Figure 14 is a side view of another wire supplying device; X-ray weaving supply device X V-XV cross-sectional view; Figure 16 is a side view of the first conveyor belt; Figure 17 is a cross-sectional view of the conveyor belt; Figure 18 is a side view of the second conveyor belt; A cross-sectional view of the belt. [Embodiment] FIG. 1 discloses a webbing machine having a rack 2, the rack being provided with a main drive shaft 4, which at least drives a weft needle 6, a woven fabric 7, a product discharge device 8 and not shown in detail. A heald device 10. The webbing machine has a warp reel 12 that carries each warp reel 14 from which the warp threads 16 are guided to the heddle device 10, wherein the warp threads open to form a shed 18. By means of a wire weaving device 20, a weft 24 is transported from a wire spool 22 to the weft needle 6, which brings a weft thread back into the shed 18. The weft loops of the preceding and following strands can be woven together, or a woven weft loop can be woven by a catching wire 26 and ensure that the catching thread is guided through another thread supplying device 28 into a place here. The needles shown. 2 to 4 disclose a first heald device 1 , wherein the heald frames 3〇 and 3〇a are each connected to a cam drive device 34 by a guide rod 32, and on the other hand, The pneumatic pullback device 36 is coupled. The cam drive unit 34 has swinging levers 38, 38a, 38b, 38c, 38d that interact with the cam 42 of a camshaft 44 at a certain drive position 40. At the driven position 46, the swinging levers 38, 38a, 38b, 38c, 38d are coupled to the guide bar 32 via the hinges 48. The pivot axes provided by the joints 48 are vertically disposed on the planes developed by the heald frames 3, 30a. Each of the driving positions 4〇, 4〇a, 4〇b, 4〇e, 4〇d 8 1323750 at the swinging levers 38, 38a, 38b, 38e, 38d, to each of the swinging wheels %, 5〇a, 50b, The distance A between 50c and 5〇d is different between two adjacent swinging levers, and each of the driven positions S 46, 46a, 46b, 46c, 46d swings the axes 5G, 5〇a, 5〇b,

The distance B between 5〇c and 5〇d is also different. As a whole, the heald frame can be moved by different strokes to form a shed that continuously expands and shrinks again, as shown in the figure. The pneumatic pull-back device 36 is formed by an air chamber 52 having a movable piston 54 whose rods 32 are coupled to each other to compress the shape of the piston at the operating frequency of the cam drive unit 34. An overpressure protection valve 56 coupled to the air chamber 52 confines the maximum pressure in the air chamber. An air pressure source 6 is coupled thereto via a one-way valve 58 for adjusting the air pressure in the air chamber 52. The air pressure source 60 is coupled to a control device not shown in detail, whereby the air pressure in the air chamber can be adjusted in accordance with the operational state of the webbing machine. Figure 5 discloses a heddle device l〇a in which the air pressure pullback device 36 is replaced by a spring pullback device 61 which acts on the frames 3, 30a.

The heald frames 30, 30a are formed by an upper rail 62 and a lower rail 64 which are coupled to each other via a heald support 66. The heald support 66, which is shown in detail in Fig. 3, has a hollow rod 68' which is made of metal or plastic which is mainly made of fiber. The hollow rods 68 are provided with slits 70 which are distributed and offset from each other on opposite sides in the longitudinal direction thereof. The upper spindle rail 62 is inserted into an upper side inlet opening 72, and the lower spindle rail 64 is inserted into the lower side inlet opening 74. At least one of the inlet openings 72, 74 has a support flange 75 that points laterally and vertically. The upper edge key rails 62, 64 are coupled to each other via a press: rod 76. At the upper edge of the hollow rod 68, a clamping bolt 78 is locked in the hollow rod 68 and pressed against the upper rail 62, and thus the rails 62, 64 are locked to each other. The safety of the ingot rail 62 and the lower spindle rail 64 is ensured by the heald support 66. As is apparent from Fig. 2, a plurality of heald 9 1323750 supports 66 are arranged along the length of the heald frame. Between the upper spindle rail 62 and the lower spindle rail 64-, there is disposed a webbing 80 having a thread grommets 82 through which a warp thread 16 can move. Figures 6 and 7 disclose a particularly preferred design of the heald frame 30 in which the webbing 80 is aligned on the upper rail 62 and the lower rail 64 by an upper buttonhole 84 and a lower buttonhole 86. In the present embodiment, a driven ingot rail 62 has a thin leg 88 which projects transversely to the ingot rail 62 and is coupled to the timing groove of the end button eye 84 of the webbing 80 with minimal clearance. In slot 90. The end grommets 84 attached to the driven spindle rails 62 fully grasp the spindle rails 62, wherein there is a gap between the legs 88 on the driven spindle rails 62 and the timing grooves 90 of the end grommets 84. Its width is 〇.〇1 to 〇.3mm. In this regard, the thickness of the leg 88 and the width of the synchronizing groove 90 need to be adjusted to each other such that the gap between the leg 88 and the synchronizing groove 90 is 0.01 to 0.3 mm. Although it is a small gap, the opening of the web which is preferably designed as a sheet may form an angle ? of 15 with the vertical line, as shown in Fig. 7. The lower ingot rail 64 can be designed to resemble the upper ingot rail, wherein a vertical gap may be 0.5 to 1 mm. In this example, the lower rail 64 is not used to drive the webbing 80, but is used to guide the heddles and to withstand the shear forces caused by the movement of the warps 16. Through the design of the webbing, the heald device can also withstand the maximum speed, for example 4000 to 6000 revolutions per minute, with only minimal noise and only a minimum of wear. 8 and 9 disclose a transmission diagram of the webbing machine, wherein the weaving transmission 92, the weft needle transmission 94, the knitting transmission 96 are from the main transmission shaft 4, and via a single-stage gear or mast transmission The secondary drive shaft 100 of the cam drive unit 34 of the heald device 10 is coupled. For the weft needle transmission 94 and the knitting transmission 96, a common disc 102 is disposed on the main drive shaft 4 by a crankshaft 104 having crankshaft pins 10 1323750 106, 108 respectively in diametrically opposed positions. 'It can be adjusted in the radial direction of the groove of the disc 1〇2 and the crankshaft ι4 so that the eccentricity can be adjusted. The crank pin 1〇6 disposed on the weft needle drive 94 interacts with a swing lever 114 via a coupling lever ι 2, which is coupled in a bendable manner via a further tie rod 116 and a swing lever 118. The last of the above is fixed to a mandrel 120 which carries and drives the weft needle 6. The woven transmission 92 is secured to the crank pin 1 〇 8 and coupled to a oscillating rod 124 via a coupling tie 122 that carries the woven raft 7. The needle driver 96 has a cam disc 126 disposed on the main drive shaft 4, and a lever 128 on a swinging lever 130 of a two arm applies a force thereto. The knitting needle 132 is fixed to the other side of the swinging rod 124 with respect to the side of the lever 128, and is applied to one side of the strip in the manufacturing process, and is used to effect the braiding of the weft thread to be woven. 10 and 11 disclose the knitting range of the webbing machine, wherein a guide plate 134 having a guiding rail 136 is disposed on one side of the knitting needle 132 from the side of the shed 18, which is configured in such a manner that the weft return line 140 When the weft needle 138 is held by the knitting needle 132, when it is fed into the shed 18, it is located below the height of the head 142 of the knitting needle 132 or at its most point 'when the weft needle 6 is withdrawn through the needle head 142 The weft foot 138 can be guided into the needle track of the needle 132. By this design, a particularly safe fit is produced and only the weft thread 138 to be processed is on the needle 132 and it is produced in a very small weave range. By this, the movement of the knitting needle is kept very small, so that the arm of the knitting needle can be used to ensure the capture of a safe and reliable weft thread. This design allows shorter needles to withstand bending, vibration and wear with less power. This can provide a greater performance of the webbing machine. Figures 12 and 13 disclose a thread supply device 20 for use with a preferred weft thread 24. The borrowing wire transfer device 144 arrives at a latitude 11 24 drawn from the reel 22 - the air pressure adjusting device 146 'is guided over the line 24 to traverse the pipe 148' which is also seated by an air blowing device 15 〇 β By the wire transfer device 144 at a fixed speed, the "weft line 24 is intermittently operated by the weft needle 6" so that the two weft threads are not woven, and the weft line 'generates a transfer 152' which is carried into the g through the air blowing device (9). Lane 148. A weft thread 24 is present between the adjusting device 146 and the weft needle 6 to use the guiding buttonhole 154. A suction device can be coupled to the conduit 148 to replace the air device 150 or can be attached. Figure 13 reveals that the wire transfer device 144 is in the ΧΙΠ-ΧΙΠ 面 face of Figure 12, which adjusts the transfer speed of the weft. The wire transfer device 144 includes a transfer roll 158 disposed on a mandrel 156 having a friction surface 160. The friction surface can be radially expanded by the acid means 162 whereby the peripheral speed of the transfer roller (5) can be adjusted. The adjusting device 162 has an adjusting block 164 disposed on the mandrel 156, which is composed of an incompressible material which is a kind of synthetic rubber, which is arranged in a waiting disk 166 and an adjusting disk 168. And can be compressed by a adjusting nut 17〇 locked on the mandrel 156. With the gradual increase in compression, the outer casing 172 of the transfer roll 158 is expanded, thereby changing its straightness and speed. The weft % to be mixed is pressed against the transfer roll 158 by a pressure roller 174 and thereby transmitted. Another type of wire transfer device 175 is shown in Figures 14 through 19, wherein a bypass conveyor belt 176 of a transfer wire 24 is disposed between the transfer mandrels 178 and the I-conical control disks 18, 182. The axial distance between the two control discs can be adjusted. Here, the control discs are tightened by a spring 184. The transmission belt 176 is guided via another steering wheel 186, the distance to which the control discs can be adjusted by a control unit 188. The conveyor belt disclosed in Figures 16 and 17 has a continuous member 19〇 having a thickness d. A plurality of transverse ribs 192 are formed on the underside of the continuous member, the height h being greater than the thickness d of the component 12 of the tie. The successor component 190 is additionally designed to have a reinforced filler 194. Another design of the transport belt 176a is disclosed in Figures 18 and 19, which are additionally provided with transverse ribs 196 on their upper side. In addition, it can be inferred from FIG. 14 and FIG. 15 that the wire transmission device further designs a pressure roller 198 between the control discs 18〇, 182 and the steering wheel I%, so that the transmission belt can be twisted and twisted. Guided by the form of bending. The filament edge 24 to be transported can be received and discharged in the guided curved field. The wire transfer device is particularly suitable for weft threads, wherein when a multi-stage webbing machine is used, that is, when a plurality of adjacent strips are simultaneously manufactured, a plurality of such transport devices are disposed adjacent to the same drive spindle 178. And a common swinging heart draws and preferentially employs a common control device 188 to facilitate its adjustment.

13 1323750 [Main component symbol description]

2 Rack 4 Main drive shaft 6 Weft needle 7 Weaving 8 Product discharge device 10 Heald device 10a Heald device 12 Warp reel stand 14 Warp reel 16 Warp 18 Hopper 20 Wire supply device 23 Wire reel 24 Weft 26 Snap wire 28 wire supply device 30 heald frame 30a heald frame 32 guide bar 34 cam drive 36 air pressure pullback device 38a-d oscillating lever 40a-d drive position 42 cam 1323750 44 camshaft 46a-d driven position 48 joint 50a -d Swing shaft 52 Air chamber 54 Piston 56 Overpressure protection valve 58 Check valve 60 Air pressure source 61 Spring pullback device # 62 Upper rail 64 Lower key rail 66 Heald support 68 Hollow rod 70 Slot 72 Opening Hole 74 inlet opening 75 support flange _ 76 pressure bar 78 clamping bolt 80 webbing 82 wire grommets 84 end grommets 86 end grommets 88 feet 90 aligning grooves 15 1323750 92 94 96 98 100 102 104 106 • 1 〇 8 110 112 114 116 118 120 122 124 _ 126 128 130 132 134 136 138 140 142 woven gear transmission weft needle drive needle drive gear / mast drive secondary drive shaft disc crankshaft crankshaft Pin Slot Coupling Rod Swing Rod Coupling Pull Rod Swing Rod Mandrel Pulling Rod Swinging Rod Cam Disc Plunger Swing Rod Knitting Needle Guide Guide Track Weft Foot Thread Return Wire Needle Head 1323750 144 Wire Transfer Device 146 Adjustment Device 148 Pipe 150 Blowing device 152 Transfer 154 Guide grommets 156 Mandrel 158 Transfer roll 160 Friction surface 162 Adjustment device 164 Adjustment block 166 Stop disk 168 Adjustment disk 170 Adjustment nut 172 Housing 174 Pressure roller 175 Wire transfer device 176 Transfer belt 176a Transmission belt 178 transmission mandrel 180 control disc 182 control disc 184 spring 186 steering wheel 188 control unit 190 continuous part

17 1323750 192 transverse ribs 194 reinforcing packing 196 transverse ribs 198 .

Claims (1)

X. Patent Application Range: L A webbing machine having a heald device (1〇, 1〇a) forming a shed (18) having a heald frame (30 '30a) for carrying a webbing (80), In addition, it has a weft needle (6) and additionally has at least one thread feeding skirt (2〇, μ), and further has a knitting needle (132) which is arranged on the shed (18) and the weft needle ( 6) on one of the opposite sides, which has a woven raft (7), characterized in that the heald frame (3〇, 3〇a) has at least one heald support (66) having a hollow rod (68), the hollow rod has an inlet opening (72) for the upper rail (62) and a lower inlet opening (74) for the lower key rail (64), which are located The upper edge of the key rail (62, 64) is coupled via a pressing rod (76) disposed in the hollow rod (68), and is locked to one end side of the hollow rod (68) and the pressing rod (76). The coaxially configured clamping bolts (78) are locked to each other. 2. The webbing machine of claim 3, wherein the at least one inlet opening (72, 74) has a lateral, vertically directed support flange (75). 3. The webbing machine of claim 1 or 2, wherein the hollow rod (68) has a slot that is distributed and offset from each other across its full length on opposite sides thereof (70) ). 4. The webbing machine according to claim 1, wherein the material of the hollow rod (68) φ is a fiber-reinforced and slidable plastic material. 5. The webbing machine according to claim 1, wherein the webbing (80) having the grommets (82) is arranged on the ingot rails (62, 64) by the end grommets (84, 86). At least the driving key rail (62) has a thin leg (88) which protrudes transversely to the spindle rail (62) and is spliced to the end of the webbing (80) with a minimum gap. In the synchronous groove (90) of (84), the end grommets (84) disposed on the driven ingot rail (62) simultaneously completely grasp the ingot rail (62)' and the driving rail (62) On the upper side, there is a gap between the leg (88) and the end grommets (84). The gap between the grooves (90) is between 0.01 and 0.3 mm. 6. The webbing machine according to claim 1, wherein the heald frames (30, 30a) are provided with swinging levers (38, 38a, 38b, 38c, 38d) at a certain driving position (40). , 40a, 40b, 40c, 40d) can be actuated by a cam (42) and connected to a heald frame (30, 30a) at a driven position (46, 46a, 46b, 46c, 46d) And the distribution of the swing axes (5〇, 5〇a, 5〇b, 50c, 50d) is perpendicular to the plane in which the heald frames (30, 30a) are unfolded, and at the same time, each drive position (40, 40a, 40b, 40c) The distance (A) between the 40d) and the swinging shafts (50, 50a, 50b, 50c, 50d) is at least different from the distance between the two swinging levers so as to be disposed on the swinging levers (38, 38a, 38b). , 38c, 38d) The heald frames (30, 30a) are able to move different sizes during production operations, and 'further further, these are in the driven position (46, 46a, 46b, 46c, 46d) The pivot axes (5〇, 5〇a, 50b, 50c, 50d) at different distances (B) have different distances to the central plane, the distribution of which is parallel to the translation of the heald frame (30, 30a) , While the expansion of the plane perpendicular to its axis and traveled through that. 7. The webbing machine of claim 1, wherein the heald frame (3〇, 30a) is movable by a body-connected driving device (34) each time it is in a certain direction of motion. In other directions of movement, it is moved by a spring pullback device (61). 8. The webbing machine according to claim 1, wherein the heald frame (3〇, 30a) is movable by a drive device (34) connected to the job in a certain direction of movement. In other directions of movement, the air pressure pullback device (36) is used, and at the same time, the air pressure pullback device has a gas volume in a separate air chamber (5), which can be connected by the body. (34) Compressed at its operating frequency. 20. The webbing machine of claim i, wherein the webbing machine has a main drive shaft (4) traversing the web transfer conveyor, and a woven transmission (92) is coupled thereto. - Weft needle transmission (94) and a knitting needle transmission (96), the same = weft needle transmission (94) and weaving # transmission (92) respectively have a swinging force 114 124) 'It is via a light tie rod (ιι2) , Lang is connected to the main drive main shaft (4) 18 〇. The misaligned crank pin (10), (10), the weft needle driving device (94) and the needle driving device (96) swing with each other, and at the same time, the line training device (10, L〇a) has a primary drive shaft (10) that is coupled to the main drive pump (4) via a gear worm drive (98). 10. According to the scope of the patent application! The webbing machine of the present invention, wherein a guide plate (134) having a guiding rail (136) is disposed on a side of the knitting needle (10) away from the shed (18), and the arrangement is such that the weft return line (14〇) on the weft: the weft thread (138) is placed below the height of the needle head (142) or the highest point of the needle (142) when it is fed into the shed (18), and when When the weft needle (6) exits through the needle head (142), it can be guided into the needle hook track of the needle needle field. U. The weaving according to the first application of the patent specification, wherein the needle (4) is arranged on a thread supply device (2〇) having a weft (24) adjusting device (146), which is designed to be pneumatically actuated. Blowing and/or suction device (150), and in the direction of the running direction of the wire, after the adjusting device (146) and before the weft needle (6), the separate guiding buttonhole for the weft (24) is arranged (ΙΜ ). The webbing machine of claim 1, wherein the webbing machine has a wire transporting device (144), in particular for the transport of the weft thread (24), which is provided with a configuration mandrel (156). And transportable and having a transfer roll (158) capable of interactively changing the peripheral speed, having a friction surface (160), the cymbal blade additionally having a same wire to be transported (24) pre-compacted to the pass: The pressure roller (174) on the roll 21 1323750 (158) is simultaneously formed by a single-shell (172) which is radially expanded by means of an adjusting device (162). 13. The webbing machine of claim 1, wherein the webbing device (175), in particular applied to the weft thread (24), is designed to have a transportable filament (24) A conveyor belt (176, 176a) that is guided to operate on a transmission mandrel (178) with a change in axial distance between the tapered control discs (180, 182) and a steering wheel ( 186) and a pressure roller (198), at the same time there is a change from the steering wheel to the transmission spindle ((7)) distance I control device c 188) ' At the same time, the transmission belt (176, i76a) is designed At least on a certain side, there are transverse ribs (192), and can be bent and guided to run between the steering wheel (10) and the pressure roller (198). In addition, the wire (24) to be transmitted is guided by the meandering curve. The park was able to be accepted and discharged. twenty two