EP0087513A1 - Loom with a rotary shed forming device - Google Patents

Abstract

Guide channels (F) for the weft threads driven by a flowing fluid are arranged on the weaving rotor. The guide channels (F) are formed by elongated, tubular channel elements (5) which have a lockable weft exit slot and are formed at their ends to form a closed guide channel (F). The channel elements (5) can be moved back and forth in the weft direction (A). When moving in one direction (A), the closed guide channel (F) is opened and a gap (S) is formed between the channel elements (5) and each channel element is moved out of its shed part. When moving in the other direction, each channel element (5) is moved into its shed part and the guide channel (F) is closed. The total adjustment path of each channel element (5) in each direction is at least the same as its length. Due to the exclusive back and forth movement in the weft direction, the drive of the channel elements can be designed in a simple manner and their length of a few centimeters reduces the number of possible leakage points of the guide channel so much that the weft thread can be introduced with suction air.

Description

The invention relates to a row shed weaving machine with a weaving rotor with combs of shed retaining elements for the warp threads to form open shed weaves moving in the warp direction and with guide channels formed from channel elements for the weft threads driven by a flowing fluid, which channel elements have a lockable lateral outlet slot for the weft thread are arranged to be movable and are designed at their front and rear ends in the weft direction in such a way that a continuous and closed guide channel is formed in their weft insertion position.

Such a row shed weaving machine is described in DE Offenlegungsschrift No. 31 11 780 (corresponds to CH patent application No. 2 440 / 80-0). In this known row shed weaving machine, each guide channel consists of two slat combs which can be inserted into the warp threads and exchangeable from these, the individual slats of which form the channel elements. The lamellae are naturally relatively thin and their end faces, that is to say their front and rear ends in the weft direction, are wedge-shaped, which facilitates the sliding together and apart of the lamella combs. The lamellas of each lamellar comb are fixed on at least one rod which extends across the width of the weaving machine and on which rods act on drive levers controlled by machine-fixed control cams.

This known row shed weaving machine should make it possible to insert the weft threads not by blown air, but by suction air, which not only mean a significant energy saving, but also a much quieter thread flight and better controllability of the weft would allow entry. However, it has been shown that, due to the small thickness of the lamellae, the guide channel has such a large number of potential leakage points that the aim of the weft insertion by blowing air could only be achieved to a very limited extent. In addition, the drive of the lamellar combs with the rods, drive levers and control cams has a large number of mechanically moved and stressed parts and thus exposed to possible wear.

The known row shed weaving machine is intended by the invention. to be improved in such a way that the weft threads can be introduced with suction air and that the guide channel with the drive and the control of the channel elements is designed as simply as possible and in particular consists only of a few and slightly stressed parts.

This object is achieved according to the invention in that the channel elements have an elongated, tubular shape, that their length is a multiple of the thickness of a compartment holding element, that the channel elements can be moved back and forth by a drive element, the movement being in one direction closed guide channel is opened and a gap is formed between the channel elements and each channel element is moved out of its shed part and when moving in the other direction each channel element is moved into its shed part and the guide channel is closed, and that the total adjustment path of each channel element in one direction is at least as large how their length is.

The use of elongated, tubular duct lamellae instead of the previous lamellae, according to the invention, increases the number of potential leakage points drastically, that is, reduced by more than an order of magnitude and the weft threads can be introduced with suction air, which gives the advantages already mentioned. The movement of the channel elements in the weft direction enables their drive and control to be simplified.

• Fig. 1 einen schematischen Längsschnitt durch den Webrotor einer Reihenfachwebmaschine,
• Fig. 2 ein Detail von Fig. 1 in perspektivischer Darstellung,
• Fig. 3 einen Schnitt nach der Linie III - III von Fig. l, und
• Fig. 4 ein Diagramm zur Funktionserläuterung.

The invention is explained in more detail below using an exemplary embodiment and the figures of the drawing; in the latter show:

• 1 shows a schematic longitudinal section through the weaving rotor of a row shed weaving machine,
• 2 shows a detail of FIG. 1 in perspective,
• Fig. 3 is a section along the line III - III of Fig. 1, and
• Fig. 4 is a diagram for explanation of function.

Figures 1 and 3 show the weaving rotor of a row shed weaving machine in the longitudinal or cross section. In operation, the weaving rotor rotates in the direction indicated by an arrow P in FIG. 3. Operation and structure of a series shed weaving machine with a weaving rotor are assumed to be known and are not explained in more detail here; in this connection reference is made to US Pat. No. 4,290,458.

According to FIG. 1, the weaving rotor has a hollow roller 1 which extends over the weaving width and is mounted on the side of the machine frame next to the warp threads and by a drive also arranged on the side of the machine frame is driven by means. As shown, the hollow roller 1 is supported on its left face by a flange 2 and on its right face by a pipe stub 3. The flange 2 is rotatable on the left machine wall, the pipe stub 3 is rotatably mounted in a housing 4 which is firmly connected to the right machine wall. The shot is inserted in the direction of arrow A from left to right. Guide combs for the warp threads and stop combs and guide channels F for the weft threads are alternately arranged on the jacket of the weaving rotor in the longitudinal direction of the hollow roller 1 and thus in the weft direction A. A total of 12 to 14 of these combs and an equal number of guide channels F are provided on the entire jacket of the weaving rotor.

With regard to the stop and guide combs, reference is made to FIG. 3; 1 and 2, the guide channels F are initially explained: each guide channel F consists of a number of elongated, tubular channel elements 5 arranged one behind the other in the firing direction A, one of which is shown in perspective in FIG. 2. The channel elements 5 have a triangular cross section and are provided on their upper longitudinal edge with a continuous longitudinal slot 6 between the two side surfaces and on their end faces each with a bevel of the same inclination. The bevel on the front end side of each channel element 5 in the weft direction A continues against the axis of the hollow roller 1 into a tongue 7 bent away from the base surface of the channel element 5 at the same inclination as the end surface. The tongue 7 then runs horizontally on this inclined part and is bent vertically at its free end against the axis of the hollow roller 1. This bent end 8 of the tongue 7 acts as a driver for the channel element 5.

The weft threads are introduced into the guide channels F formed from the channel elements 5 by means of a flowing medium, in particular air, namely suction air. For this purpose, a connection element 9 is arranged next to the foremost channel element 5 of each guide channel F in the weft direction A, from which a hose 10 or another flexible line leads to a suction device (not shown). The connection elements 9, which are arranged outside the warp threads, have the same cross-section and the same bevel on their end face facing the adjacent channel element 5 as this. They also have a driver tongue 11 projecting against the axis of the hollow roller 1, the shape of which is arbitrary within wide limits and they do not have a longitudinal slot 6, but are closed on their jacket.

With each weft insertion, a weft thread is sucked through the channel elements 5 of each guide channel F in the weft direction A. The respective shed is open and the warp threads K lie above and below the guide channel (upper guide channel F in FIG. 1). After each weft insertion has ended, each weft thread leaves its guide channel F through the longitudinal slots 6 in the direction away from the axis of the hollow roller 1. The compartment must then be closed, which is made possible by shifting the channel elements 5 in the weft direction A (lower guide channel F 'in FIG. 1). As soon as the new shed is open, the channel elements 5 are pushed back into the weft direction A and the guide channel F is newly formed.

The displacement of the channel elements 5 in the weft direction A and opposite to this takes place by means of a drive arranged between the hollow roller 1 and the channel elements 5 means, which act on the drivers 8 and 11 of the channel elements ₅ and the connecting elements 9. According to the illustration, the drive means for each guide channel F are formed by two bands or flat bars 12 and 13 which extend over the weaving width and are arranged one above the other, both of which are fastened to the flange 2 at their end on the weft entry side via a tension spring 14 and 15, respectively. One of the bands, the outer band 13 according to the illustration, is connected to a drive mechanism at its end on the exit side of the shot. The bands 12 and 13 are each provided with recesses 16 and 17, respectively, in which the drivers 8 and 11 engage. Thus, when the bands 12 and 13 move in the weft direction A and opposite thereto, the channel elements 5 and the connecting elements 9 experience the same movement.

According to FIG. 1, the drive mechanism of the belts 12 and 13 comprises a cable 18, one end of which is anchored to the outer belt 13 and the other end of which is anchored to the hollow roller 1, a roller 19 over which the cable 18 is guided, and the roller 19 control cam 20. The control cam 20, which is milled into a sleeve 21 which is fixedly connected to the housing 4, is machine-fixed. The roller 19 is fastened on a rod 22, which is mounted on two bearing rods 23 so that it can be moved back and forth in the weft direction A and which carries at one end a sliding block 24 which is in engagement with the control cam 20. The bearing rods 23 are fastened on a disk 25 which is fixedly connected to the pipe stub 3 and therefore rotatable relative to the housing 4 and thus to the control cam 20.

When the hollow roller 1 and thus the weaving rotor with the guide channels F rotate, each of the rods 22 also rotates and the sliding blocks 24 pass through the control cam 20. Each roller 19 is displaced between the two extreme positions shown above and below in FIG. 1 and each outer belt 13 and each channel element 5 experiences via the rope 18 by the pulley effect of roller 19 and rope 18 a displacement twice as large as its role 19. Since the drivers 8 and 11 of the channel elements 5 and the connecting elements 9 each have the recesses 16 and 17 of both Projecting bands 12 and 13, the movement of each outer band 13 is also transmitted to the inner band 12 via these drivers 8 and 11.

The control curve 20 and the arrangement and dimensioning of the recesses 16 and 17 of the strips 12 and 13 are coordinated with one another such that, starting from the position of the channel elements 5 shown in FIG. 1 above, in which they form a closed guide channel F, the channel elements 5 are moved as follows: As soon as the weft insertion in a specific guide channel F has ended, the roller 19 is moved in the weft direction A and thereby also the outer band 13. In a first stage, a gap S is made between the channel elements 5 for the passage of the Warp threads K formed from the lower to the upper compartment. The size of this column S, which in the practical embodiment is approximately 1 to 2 mm, is limited by the inner band 12 and likewise by the inner band 12 the individual columns S are maintained during the further displacement of the channel elements 5.

In this connection, it should also be pointed out that the flange 2 has a stop 26 for each guide channel F and a bore 27 on each stop 26 through which the weft threads are sucked into their guide channels F. Each weft thread is brought into or to the respective bore 27 by a device, not shown.

By a further movement of the roller 19 in the weft direction A, all channel elements 5 are displaced in a second stage in the weft direction A until the guide channel F is removed from the stop 26 by a length of a channel element 5 plus the width of a gap S. The gaps S remain and the guide channel comes into position F '. Due to the shape of the tongue 7, the warp threads K of the lower compartment are pushed into the upper compartment during this displacement of the channel elements 5, which occurs on the way through the gap S between the channel elements 5. In Fig. 1 below, all the warp threads K are also drawn in the upper compartment in the space free of channel elements 5 following the stop 26. This is not necessary because the warp threads K will occupy a position between the upper and lower shed depending on the shed geometry in this free space. When the weaving rotor continues to rotate, the channel elements 5 are rotated out of the warp thread plane and all the warp threads K can assume their closed shed position in which the weft stop takes place.

The weaving rotor then performs a relatively long rotation with the open guide channel F 'until this open guide channel F' re-enters the warp threads K, which have meanwhile carried out a change of shed. In the channel element 5 on the shot entry side free space between the stop 26 and the guide channel F ', the warp threads K are thus already in the upper and lower compartment, that is, the compartment is open. Over the remainder of the weaving width, the warp threads of the sub-compartment could not get into it because of the channel elements 5 located there, but lie under tension on the outer edge of the channel elements 5 with the slot 6.

Now the roller 19 is moved in the opposite direction to the firing direction A and the channel elements 5 are displaced against the stop 26 in a third stage until only the gaps S which are retained during this displacement are open. The third stage, in which the displacement of the belts 12 and 13 is supported by the springs 14 and 15, is therefore the reverse of the second stage. When each channel element 5 is displaced, the warp threads K provided for the lower compartment pass through the gap S into the lower compartment, so that each channel element 5 is pushed into an open compartment. At the end of the third stage, the inner band 12 abuts with its end face on the shot entry side against a stop 28 mounted on the flange 2 and can no longer move against the flange 2.

The guide channel F is now in the same position as after the first stage, that is to say only the gaps S are still open. Subsequently, the roller 19 is moved still further opposite to the weft direction A and in a fourth stage, which runs in the opposite direction to the first, the column S is closed and the guide channel F has again reached the position shown in FIG. 1 and is for a weft insertion ready. The spring 15 ensures that the channel elements 5 against each other and are pressed against the stop 26, the guide channel F is therefore tight in the longitudinal direction and has no leaks.

The processes for opening and closing the thread channels F, which are only explained here on the basis of the functional sequences, will also be described quantitatively later with reference to FIG. 4, the arrangement and size of the recesses 16 and 17 and the size of the adjustment paths being discussed in particular.

• Wie den Fig.2 und 3entnommen werden kann, weist jedes Kanalelement 5 an seinen beiden Seitenflächen je zwei Vorsprünge 29 auf. Gemäss Fig. 3 sind auf der Hohlwalze 1 lamellenartige Organe 30 angeordnet, welche einerseits die Kanalelemente 5 tragen und anderseits durch Einwirkung auf die Vorsprünge 29 den Schlitz 6 schliessen. Die Organe 30 weisen an ihrem von der Hohlwalze 1 nach aussen ragenden Ende ein nach aussen offenes Maul auf, welches durch zwei Seitenteile 31 und durch zwei Auflagen 32 begrenzt ist. Die lichte Weite zwischen den Auflagen 32, auf denen die Kanalelemente 5 aufliegen, ist grösser als die Breite der Zunge 7. Gegen die Hohlwalze 1 hin schliesst an die Auflagen 32 eine Durchbrechung 33 an, in welcher die Bänder 12 und 13 das Organ 30 durchsetzen. Die Organe 30 umgreifen also mit der Durchbrechung 33 die Bänder 12 und 13 und tragen und führen mit den Auflagen 32 die Kanalelemente 5. Das Maul der Organe 30 weist einen dreieckigen Querschnitt wie die Kanalelemente 5 auf. Dieser Querschnitt ist jedoch grösser, sodass, sobald und solange die Vorsprünge 29 gegen die Seitenteile 31 verschoben sind, der Schlitz 6 offen ist. Wenn die Kanalelemente 5 so verschoben werden, dass die Vorsprünge 29 zwischen die Seitenteile 31 gelangen, dann werden die die Vorsprünge 29 tragenden Seitenflächen der Kanalelemente 5 zusammengedrückt und der Schlitz 6 wird geschlossen. Da die Organe 30 fest auf der Hohlwalze 1 angeordnet sind, werden bei der beschriebenen Verschiebung der Kanalelemente 5 in Schussrichtung A und entgegengesetzt zu dieser die Schlitze 6 automatisch geöffnet und geschlossen.

It has already been pointed out that the weft is inserted by suction. This requires a guide channel F which is sealed on all sides. Up to now it has been described how the guide channel F is closed in the longitudinal direction. Of course, it must also be tight in the radial direction, that is, the slots 6 of the channel elements 5 that serve for the weft thread exit from the guide channel F must also be closed when the weft is inserted. This is done by the following means:

• As can be seen in FIGS. 2 and 3, each channel element 5 has two projections 29 on its two side surfaces. 3, lamellar organs 30 are arranged on the hollow roller 1, which on the one hand carry the channel elements 5 and on the other hand close the slot 6 by acting on the projections 29. The organs 30 have at their end projecting outwards from the hollow roller 1 an outwardly open mouth which is delimited by two side parts 31 and by two supports 32. The clear width between the supports 32, on which the channel elements 5 rest, is greater than the width of the tongue 7. Towards the hollow roller 1, an opening 33 adjoins the supports 32, in which the Bands 12 and 13 pass through the organ 30. The organs 30 thus grip the bands 12 and 13 with the opening 33 and carry and guide the channel elements 5 with the supports 32. The mouth of the organs 30 has a triangular cross section like the channel elements 5. However, this cross section is larger, so that as soon as and as long as the projections 29 are displaced against the side parts 31, the slot 6 is open. If the channel elements 5 are displaced such that the projections 29 pass between the side parts 31, the side surfaces of the channel elements 5 carrying the projections 29 are compressed and the slot 6 is closed. Since the organs 30 are arranged firmly on the hollow roller 1, the slits 6 are automatically opened and closed in the described displacement of the channel elements 5 in the weft direction A and opposite thereto.

The slots 6 are about 1 to 2 mm wide in the open state, which is sufficient for the exit of the weft thread. This is because the weft thread is automatically moved against and out of the slot 6 by the warp threads K entering the upper compartment when the guide channel F is opened, which is further supported by the triangular cross section of the channel elements 5.

So that the slots 6 are opened automatically when the projections 29 are pulled out of the mouth of the organs 30, the channel elements 5 are manufactured such that they have a slot 6 of the desired width in the idle state. The channel elements 5 are integrally molded with the tongue 7 and the driver 8 and consist of a suitable plastic, for example polyamide 6. So that the slot 6 with the least possible effort can be closed, the channel elements 5 have on the two edges between the base surface and the two side surfaces a wall thinning (so-called "film hinge") in the form of a groove 34.

FIG. 3 shows, in a cross section of a section through the weaving rotor shown schematically in FIG. 1, the arrangement of the stop or. Guide combs and guide channels F on the jacket of the hollow roller 1.

The stop combs 35 consist of evenly spaced stop slats 37 for striking the inserted weft threads, the guide combs 36 consist of guide slats 38, between which the holding or retracting positions of the warp threads K are alternately arranged. The compartment holding members for the high compartment position are formed by projections 39 on one side of the guide slats 38. Since the warp threads K rest on the compartment holding members 39 for the high compartment position and are tensioned, no special compartment holding members need to be provided for the deep compartment position, but it is sufficient if in their place there is an intermediate space extending up to the jacket of the hollow roller 1. Suitable spacer elements 40 are provided between the lamellae of the stop combs 35 and the guide combs 36.

The warp threads K hold the warp threads K in their up or down position over the entire wrap angle between the warp threads and the weaving rotor. The weaving compartments formed in this way migrate in succession to the fabric stop edge, in the time in which the compartments are open, a weft thread is inserted into each compartment in a staggered manner.

The part of the stop lamella 37 and the guide lamella 38 projecting beyond the jacket of the hollow roller 1 has approximately the shape of a finger curved counter to the direction of rotation P of the weaving rotor, the inner edge of the guide lamella 38 and the outer edge of the stop lamella 37 leading in the direction of rotation P being one over the weaving width limit reaching channel-like space 41, in each of which a guide channel F is arranged.

The hollow roller 1 is provided on its jacket with L-shaped grooves parallel to the axis of the hollow roller 1, in which the stop and guide combs 35 and 36 are held. Between the grooves of each pair of combs, the hollow roller 1 below the channel-like space 41 has a groove 42 which extends over the weaving width and in which the lamellar elements 30 and the belts 12 and 13 are arranged. The lamella-like organs 30 protrude into the channel-like space 41 with their open mouth carrying the channel elements 5.

The stop and guide slats 37 and 38 forming the stop and guide combs 35 and 36 correspond approximately in thickness to a conventional leaf tooth. The gaps for the lowering of the warp threads are also about as thick as a leaf tooth. The compartment holding members 39 for the high position of the warp threads, however, have a multiple of this thickness. When changing articles, the stop and guide combs 35 and 36 are usually exchanged. On the channel elements 5 and Thus, the type of article and the type of weft and warp material used have no influence on the guide channels F, so that the channel elements 5, the organs 30 and the bands 12 and 13 together with their drive (FIG. 1) are not exchanged when the article is changed will need.

4 schematically shows the opening and closing of a guide channel F using three different states I, II and III. For each of these conditions, the stop 26 of the flange 2, the position of the channel elements 5 and the bands 12 and 13 are shown. Below the sectional view of the belts 12 and 13, a schematic plan view of these belts is shown, from which the position and size of the recesses 16 and 17 and the position of the drivers 8 in these recesses can be seen. For the sake of simplicity, only four channel elements 5 ₁ to 5 _{4 are} shown.

In state I, the guide channel F is closed. By moving the belts 12, 13 in the direction of arrow B (first stage), the gaps S are opened, which corresponds to state II. By shifting the bands in the direction of arrow C, state III is reached (second stage), in which the guide channel is fully open, that is, there is a distance between the stop 26 and the adjacent channel element 5 ₄ of the length of a channel element plus one slit width and all slits S are open. In the third stage the guide channel returns to state II by shifting in the direction of arrow D and in the fourth stage by shifting in the direction of arrow E back to state I.

The length of a channel element 5, which in the practical embodiment is approximately 100 mm, is denoted by L, the width of a gap S by b. When opening the column S in the first stage, the first channel element 5 ₄ after the stop 26 must be moved by the length b in the direction of the arrow B, the second channel element 5 ₃ by the length 2b and so on. The guide channel F is opened from the front, i.e. from the weft thread exit side, i.e. first the channel element 5 ₁ in the direction of the arrow B is only displaced by the length b, then the shifting of the next one begins, while the first one is shifted further and finally it becomes at the stop 26 adjacent channel element 5 ₄ shifted by the length b. The connection element 9 (FIG. 1) is deliberately not mentioned here. Because there is not occupied by warp threads need to be formed 5 ₁ no gap between it and the forward channel element and its driver 11 could be integral with the band. 13

The driver 8 of the foremost channel element 5 ₁ could also be firmly connected to the outer band 13. As shown, however, this driver 8 projects into a recess 17 whose width a is somewhat greater than the thickness c of the driver 8. The width of the recess 17 for the driver 8 of the channel element 5 ₂ following the foremost channel element 5 is a + b. In general, the width of the recess 17 for the driver 8 of the nth channel element is a + (nl) b. The mutual distance between the front edges of the recesses 17 in the direction of arrow B corresponds to the length L.

The inner band 12 serves to maintain the opening of the gaps S during stages 2 and 3.

Since this band is not moved directly, but only indirectly via the drivers 8 moved by the outer band 13, which protrude into the recesses 16 of the inner band 12, the width ratios in the recesses 16 are reversed as in the recesses 17. This means that the channel of the foremost element 5 ₁ associated front recess 16 is the largest and the rearmost recess 16 has the smallest width. In the state I, all the recesses 16 have a distance d between their rear edge and the front side of the driver 8 which is greater than the driver thickness c. This is so that when state I is reached after the fourth stage, when the gaps S are closed again, the spring 15 (FIG. 1) can pull all the channel elements 5 against the stop 26 and thereby seal the guide channel F. It is advantageous if the cable 18 (FIG. 1) is also attached to the band 13 with play so that the spring 15 can securely seal the guide channel F.

The total width of the rearmost recess 16 associated with the rearmost channel element 5 ₄ is d + b, the width of the next recess 16 is d + 2b and the width of the foremost, nth channel element is d + (nb). When comparing the widths of the recesses 16 and 17, it should be noted for the factor n that in the formula for the recesses 16 for the channel element 5 directly at the stop 26 and in the formula for the recesses 17 for the channel element 5 directly at the connecting element 9 ( Fig. L) n = 1.

After the first stage, all drivers 8 rest on the front edge of the recesses 16, as a result of which the inner band 12 also acts in the direction of the arrow against the force of the spring 14 (FIG. 1) direction C is moved. As can be seen from the diagrams for the states II and III, the drivers are at the same time on the rear edge of the recesses 17 and are thus, as it were, clamped between this rear edge and the front edge of the recesses 16. This ensures that the gaps S remain open in the second and third stages and are only closed again in the fourth stage after the end face of the inner band 12 has hit the stop 28 (FIG. 1).

Claims (16)

1. Row shed weaving machine with a weaving rotor with combs of shed holding organs for the warp threads to form open sheds moving in the warp direction and with guide channels formed from channel elements for the weft threads driven by a flowing fluid, which channel elements have a lockable lateral outlet slot for the weft thread, arranged to be movable relative to one another and are formed at their front and rear ends in the weft direction in such a way that a continuous and closed guide channel is formed in their weft insertion position, characterized in that the channel elements (5) have an elongated, tubular shape in that their length is many times the thickness of a compartment holding element (39) and that the channel elements can be moved back and forth by a drive element in the weft direction (A), the closed guide channel (F) being opened when moving in one direction (B, C) and a spa between the channel elements lt (S) is formed and each channel element is moved out of its shed part and when moving in the other direction (D, E) each channel element is moved into its shed part and the guide channel is closed, and that the total adjustment path of each channel element in one direction is at least as large as whose length is (L). 2. Row shed loom according to claim 1, characterized in that the channel elements (5) have a cross section with a shape tapering in the direction away from the axis of the weaving rotor and that the outlet slot (6) is in the most distant region of the said axis Channel elements is arranged. 3. Row shed loom according to claim 2, characterized in that said cross section is triangular and one of the sides of the triangle is parallel to the base of the channel elements (5) and the outlet slot (6) on the outer corner of the triangle and is parallel to the longitudinal axis of the channel elements . 4. Row shed weaving machine according to claim 3, characterized in that means are provided to move the two side surfaces of the channel elements (5) against each other for closing the outlet slot (6). 5. Row shed weaving machine according to claim 4, characterized in that said means are formed by stop members (30) arranged in a fixed manner on the weaving rotor and by projections (29) provided on the side faces of the channel elements (5), the closing of the outlet slots ( 6) when moving the channel elements in the other direction (E). 6. Row shed weaving machine according to claim 5, characterized in that the channel elements (5) on their front and rear end faces each have a bevel including an obtuse angle with the weft insertion direction (A), to which bevel on the front end side in the weft direction (A) Tongue (7) adjoins, which, following the channel element, has a portion which runs obliquely with respect to the weaving rotor and is designed as a driver (8) at its free end. 7. Row shed weaving machine according to claim 6, characterized in that when each channel element (5) is moved out of its shed part, the warp lying in the lower shed threads (K) through the sloping portion of the tongue (7) to the adjoining end face of the channel element and from there through the gap (S) to the outer edge of the channel element. 8. row shed loom according to one of claims 1 to 7, characterized in that the length (1) of each channel element (5) is greater than 10 mm and preferably about 100 mm. 9. row shed loom according to one of claims 1 to 7, characterized in that the weaving rotor has a stop (26) for the closing movement of each guide channel (F), and that each guide channel is connected to a suction device (10) for weft insertion. 10. Row shed loom according to claim 9, characterized in that the stop (26) is provided on the weft thread entry side of the weaving rotor and that the movement of the channel elements (5) in one direction (B, C) in the weft direction (A) and in the other Direction (D, E) is opposite to this. 11. Row shed weaving machine according to claims 6 and 9, characterized in that between each guide channel (F) and the axis of the weaving rotor two band-like elements (12, 13) serving as drive elements for the channel elements (5) and extending over the weaving width are arranged, which are provided with recesses (16, 17) into which the drivers (8) of the tongue α (7) of the channel elements engage. 12. Row shed loom according to claims 10 and 11, characterized in that the band-like elements (12, 13) are arranged one above the other and are anchored at one end via a spring (14, 15) on the weft thread entry side of the weaving rotor, and that at least one the band-like elements is connected to a drive at its other end. 13. Row shed weaving machine according to claim 12, characterized in that the drive comprises an arm (22) controlled by a control cam (20) with a roller (19) mounted thereon and a rope (18) guided over the roller, one end of which on the a band-like element (13) and the other end of which is anchored to the weaving rotor. 14. Row shed weaving machine according to claim 13, characterized in that the control cam (20) is arranged in a machine-fixed housing (4) and the arm (22) is mounted on a part (25) connected in a rotationally fixed manner to the weaving rotor. 15. Row shed weaving machine according to claims 5 and 12, whose weaving rotor has the shape of a hollow roller extending across the weaving width with alternately arranged first and second combs of stop lamellae for the weft threads or guide lamellae for the warp threads, the shed holding elements being arranged within the second combs are characterized in that each second lamella comb (36) is assigned a groove (42) on the jacket of the hollow roller (1) parallel to its axis over the weaving width and in which the stop members (30) are arranged. 16. Row shed weaving machine according to claim 15, characterized in that the stop members (30) have at their end remote from the axis of the hollow roller (1) an open, the channel elements (5) partially enclosing mouth, the side edges (31) for engagement with the Projections (29) of the channel elements are provided such that the mouth is closed off against the axis of the hollow roller by projections (32) carrying the channel elements and that a recess (33) surrounding the band-like elements (12, 13) adjoins these projections.

Images