KR790000949B1 - Fluid jet loom - Google Patents

Abstract

A shuttless loom in which weft was inserted into a formed warp shed by a fluid (water or gas) was described. The weft yarn was drawn from at least two sources in such a way that a group of weft yarns was inserted from the second source. The weft was selectively fed by a program controlled driven feed roll(10,11) and an associated fluid jet nozzle.

Description

Fluid Injection Looms

Figure 1 is a plan view of a loom made in accordance with the present invention, with some of the looms shown in sketch.

Figure 2 is a partial elevation view of a loom made in accordance with the present invention.

Fig. 3 is a plan view of the main parts of the loom shown in Fig. 1, and shows the relative position with other parts of the loom.

Figure 4 is an elevation of another part of the loom of Figure 1.

Figure 5 is a layout plan of the parts shown in Figure 4.

Figure 5a is an enlarged detail of the instrument shown in Figure 5.

Figure 6 is an elevation of another part of the loom shown in Figure 1.

Figure 7 is a partial cross-sectional view of the loom section shown in Figure 6.

Figures 8 and 9 show the variations of the parts of the arrangement shown in Figures 1-7.

Figure 10 is a schematic representation of the additional indictment of the modified instrument shown in Figure 8.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shuttleless loom, and more particularly to a weaving machine for inserting weft yarns by fluid injection, such as water or gas, through formed slope openings. The loom targeted in the present invention is formed of a detachable pellet at the end of the weft yarn, whereby the weft yarn is propelled by a fluid spray or a mechanical method across the warp yarn.

This type of loom is referred to herein as "fluid jet loom" for convenience. A fluid spray loom is a conventionally known machine, in which a weft thread is inserted into an opening formed therein, and a means for strongly pulling the weft yarn before it is cut at the sides of the fabric is provided. In such a conventional loom, since only one indentation device is provided, there have been many restrictions in forming a pattern. Even if a plurality of strands are inserted through this indentation device, the pattern formed by malaria injection in the arrangement of the openings is limited.

A method of alternately inserting separate weft yarns from each nozzle using two nozzles has been proposed, but in this method, wefts can be alternately inserted, but only two different weft yarns are used. There is a restriction. An object of the present invention is to provide a fluid spray loom that can form various patterns. That is, by providing an entrapment device from one or more sources (which has not been possible so far) and then inserting the wefts from one source, inserting another group of wefts from another source. Alternatively, wefts can be inserted alternately.

One feature of the present invention is that various patterns can be formed by an injector which can temporarily stop the weft supply from one source and receive the weft supply from another source in the meantime.

To describe in more detail the features of the present invention, two or more weft feeder is provided, each of these devices is adapted to supply the weft to the fluid injection port, one or more for a certain time to these injection holes There is a device for selectively disconnecting the supply position of the weft, and in the meantime, there is a device for supplying the weft by operating the supply device of the other weft. You have one or more programmers for patterning fabrics produced using. Define the "incremental time" as follows: That is, it means the time taken to insert one weft yarn from the weft supplying device into the inclined opening, cut the body needle, and then move the sea to a position where the next weft can be inserted. 1 shows a fluid spray loom made in accordance with the present invention. There are weft carriers for transporting and supplying two weft packages (P) and (P '), which are located in the proper place between the heald frame (H) and the warp beam (W), and the height of the warp sheet (S) Slightly higher position

In front of the weft carrier, there is a guide and tension device (T), and the weft (P) and (P ') come out of the weft package (P), (P') and point it to the entrance of the weft storage (SE). Is delivered. Between the tension device (T) and the weft storage prosecution (SE), a weft driving roller (DR) is installed for each of the two weft yarns, and the device includes two rollers (10) and It consists of (11) so that weft (P) or (P ') passes between two rollers. These two rollers 10, 11 are actively driven by a power source. A pulley 12 is mounted on one roller shaft 10a, and a belt 13 is wound around the pulley 12. The belt 13 is also wound around the drive pulley 14, and the drive pulley 14 is adapted to receive a force supply directly from the power source. A small cogwheel 15 is arranged on the shaft 10a of the roller 10, and the small cogwheel 15 is formed on the shaft 11a of the roller 11 and Interlocked.

The rollers 11 are moved by the brackets 17 of the pivotable arm 18, thereby causing the rollers 10 and 11 to be separated from each other for an incremental time to the rollers 10 of the rollers 11. The relative position with respect to can be changed, so weft (P) and (P ') are pulled from the weft package (P), (P') because the weft (P) and (P ') are not included when the loom operates. It does not come out. However, since the small cogs 15 and 16 are engaged with each other in the position where the rollers 10 and 11 are maximally isolated, the relationship between the supply of the wefts P and P 'to the reservoir SE is provided. Rollers 10 and 11 continue to rotate without.

The apparatus which raises and lowers the roller 11 installed so that rotation is possible is mentioned later. Small cogs 15 and 16 in the figure are indicated by chain lines and appear to be larger in diameter than rollers 10 and 11 associated with them. However, this is not necessarily the case, and as shown in Figure 3, the small cogs and the rollers have practically the same diameter.

Weft holding devices (FIGS. 4 and 5) are provided in front of the S.E. These holding devices are each composed of a pair of disks 19 and 1aa, through which wefts P or P 'pass. One disk 1aa can move far or near from another disk 19, so that the wefts P or P 'can move freely between the disks when they are far away, but when they are close they are completely gripped and cannot move.

The weft reservoir (SE) has a hollow “U” shape, and at the base of the “U” there is one hollow connector 21, which is connected to a suction device (not shown). Air is drawn through the U's arm, which continues to pull the weft. One strand of weft (P) passes through a pair of rollers (10), (11) into one arm of the letter "U", and the other strand (P ') passes from another pair of rollers (10), (11). Pass through the other arm of the letter “U”.

The loop of weft lupe passes from the rollers (10) and (11) into the arm located on one side of the U-shape and out of the same arm of the U-shape. At this time, the weft thread passes through the inlet guide 22 and the outlet guide 23, respectively, the end of the loop-pass passing through the guide 23 is directed to the disk (19), (19a).

Tension device (T) is composed of a pair of disks 24, 25, among which the disk 25 receives a constant load and compresses the wefts passing therebetween to the wefts (P) or (P '). Give the necessary tension.

The wefts P and P 'pass around the guide 26 before passing through the rollers 10 and 11, respectively. The guides 26 are mounted at the free ends of the support arms 27, and these support arms are fixed to a portion 28 of the loom, respectively, and the shafts 10a of the rollers 10 are attached to these portions 28. It is installed. The pivotable arm 18 is connected to the part 28 of the lower stop part of the feed end by the pivot pin 29. As shown in FIGS. 2 and 3, the pivotable arm 18 has a spring 30 at its free end, and the spring 30 has a hook 30a at the end thereof, so that the hook ( 30a) is also coupled to the holding pin 31 fixed to the portion 28 of the loom.

A lever 32 is provided at the other end of the arm 18, which is connected to the arm 18 and to the core 33a of the slanoid 33. For the sake of clarity, one of the arms 18 is omitted in FIG. 3, whereby a small cogwheel 15 is shown. A pair of conductive wires 34 and 34a are formed on the dasolenoid, respectively. These leads are connected to a pair of photocell detectors, and the leads from these detectors are connected to photocells 35 and 35a (FIGS. 6 and 7).

Photocells 35 and 35a (along with photocell 36 to be described later) are mounted on carrier bar 37 (FIG. 6), which faces the groove plate on one side of groove plate 38. The program element 39 passes through the other side of the groove plate 38. The program element 39 used for the loom of the present invention is in the form of an endless band of a flexible material such as a card, on which the strips 40, 41 and 42 of the reflective tape are fixed. The strip 40 is positioned to pass through the groove plate 38 side by side with the photovoltaic cell 35, the strip 41 is adapted to pass through the groove plate side by side with the photo cell 35a, and the strip 42 is connected with the photo cell 36. It passes through the groove plate 38 side by side. The lengths of the strips 40, 41 and 42 are such that the function of the loom is performed while each strip passes through the groove plate 38.

In this case, the strip 40 serves to feed the weft P 'to the warp sheet, and the strip 41 serves to feed the weft P to the warp sheet. 42 causes the solenoid to change the injection stage so that the selector valve SV can insert the weft P or P 'into the opening of the inclined sheet. This operation is described in more detail below.

The program prosecution 39 has holes 43 at its edges, which are connected to the double drive sprocket 45 by pins 44, which are installed on the drive shaft 46. The drive shaft is rotated by a suitable drive shaft (not shown) of the loom. In the position where the program prosecution 39 passes through the groove plate, the program prosecution 39 is supported by the support plate 47.

In the position parallel to the edge of the fastener of the fabric near the edge of the inclined sheet (S), there is a fluid injection upper end (I.H), which can reciprocate horizontally in the guide. I.H. is intended to receive fluid from a selector valve device (S.V.), and S.V. has a conduit 48 from a pump (not shown). The fluid is intermittently supplied to S.V., and the fluid injection is supplied to the gasoline tank as the supply time takes place simultaneously with the operation of the loom. A valve 48a operated by a cam is provided in the fluid conduit 48 for this purpose.

I.H. is provided with two injection nozzles 49 separated from each other, and the weft yarns P and P 'pass through each nozzle. The nozzle 49 is of a known type, each of which is provided with a fluid (water or gas) inlet 50, which is connected to the derivative conduits 51 and 52, each of which is connected to each other. It is connected to the selector valve (SV). By this arrangement, the fluid spray is connected to the nozzle 49 necessary for use, and ejects the weft yarn by a certain length across the opening so that the body needle can be moved by the body 53.

At the location of the fastener of the fabric and near the IH, a weft cutter 54 (convenient for prosecution such as a heated blade) is installed, which is an inclined sheath when the body 53 moves against the weft. At the edge of the weft (P) (P ') serves to cut.

As described above, the I.H. can reciprocate and the selector valve S.V. can also reciprocate so that these two elements can be adjusted to operate simultaneously using the selector S.M. shown in FIG. 4 and 5 show details of S.M. The selection mechanism (S.M.) is located on one side of the loom and is conveniently located between the driving roller (D.R.) and the upper inlet (I.H.).

S.M. is composed of a chain sprocket 55 mounted on a shaft 56 of a suitable loom. The variant sprocket 55 is wound by a chain 57, and the chain 57 is wound around the drive chain sprocket 58 installed in the sprocket shaft 59. The sprocket shaft 59 is provided with a selection cam 60, which is installed in the cam follower 61 necessary for operating the part of S.M.

The cam follower 61 is installed on the cam lever 62 at an intermediate position of the end thereof, and the cam lever 62 has a recess 63 which is recessed at the free end of the upper end thereof. Same thing. The cam lever 62 is mounted on the selection shaft 63 which can vibrate, and the lever 62 with the projection 64 is provided between the selection shaft 63 and the cam follower 61. The projection 64 is provided with a turning pin 65 connected to the lower catching element 66, and a free end of the lower catching element 66 has a recessed portion 67 which is dug into its lower side. . A trapping element stop 68 is provided above the lower trapping element 66 and on the cam lever 62.

On the cam lever 62, a pin 69 is provided near the capture point stop 68, and one end of the pin is attached with a light capture spring 70, and the other end is a lower capture point. Attached to (66), the lower capture prosecut 66 is gripped with respect to the capture protractor stop (68).

A valve change lever arm 71 is connected to an end of the selection shaft 63, which is pivotally connected to the valve change lever 72, and a saddle (Saddle) at the other end of the valve change lever 72. 73) is attached. This saddle 73 serves to actuate the selector valve S.V. At the other end of the selection shaft 63, a boss 74 with two arms is mounted. One arm 75 extends on a horizontal plane and the other arm 76 extends on a vertical plane. A spring 77 is connected to the arm 75, which spring 77 attempts to turn the arm 75 counterclockwise. The fluid injection port conversion lever 78 is rotatably attached to the arm 76. The conversion lever stopper 79 is fixed in the vicinity of the arm 76. The conversion lever stopper allows the arm 76 to be subjected to the prescribed motion of the fluid injection port conversion lever 78. The fluid injection port converting lever 78 is connected to I.H. by a link 80.

As described above, the lower trapping element 66 has a recess portion 67, and an extension portion 71a extending upward is installed on the conversion lever arm 71 so as to cooperate with the recess portion. The free end of the extension portion 71a has a groove portion 81. The length of the extension portion 71a is the length of the trap 66 when the cam lever 62 vibrates when the two recesses 67 and 81 are separated when the catch 66 is in contact with the stopper 68. ) And the extension part 71a of the conversion lever arm 71 do not contact.

The dripping rod 83 extends upward from the trapping element 66 and is guided by the sleeve in the fixed guide 82. The upper end of the dropping rod 83 is connected to the selection arm 84, which is pivotably connected to the shaft 85 of the fixing portion 86 of the loom. The selection arm 84 has a catching point 87, which is adapted to cooperate with the recess 63 of the cam lever 62, and the cam type on the cam lever 62 if necessary according to the program. The eastern portion 61 determines the position of the cam lever 62 so that the cam 60 is completely retained. In order to control the movement of the selection arm 84, an arm 84 is connected to the link 88, which is fixed to the core of the solenoid 89. The conductive wire 90 of the solenoid 89 is connected to the photovoltaic cell 36. The link 88 is attached to one end of the spring 91, the other end of the spring 91 is connected to the fixed arm 92, the fixed arm 92 is fixed to the loom 86 It is installed in (93). The selection arm 84 is knitted by the leaf spring 94, whereby the capture element 87 is positioned so that it can be placed in the movement path of the cam lever 62.

The saddle 73 attached to the valve conversion lever 72 is composed of a pair of arms that are separated from each other from the end of the selector valve S.V. Each arm 73 is attached with valve piston rod actuating members 95, 95a, each of which is positioned locally on the arm 73. As shown in FIG. The piston rods 95 'and 95'a protrude from the cylinder 96 of the selector valve, and since the piston rods are externally spring loaded, the head 101 of the piston rod is connected to the valve inlet member. Abut the ends of (97) (98), thereby closing the hole (99) in it. The inlet member 97 is connected to the fluid conduit 51, and the inlet member 98 is connected to the fluid conduit 52. The holes 99 of the inlet members 97 and 98 have diameters larger than the diameters of the piston rods 95 'and 95a' so that these piston rods pass through them. The hole 99 is connected to the radial hole 100 and is also connected to the fluid conduits 51 and 52 at the same time. The piston rods 95 'and 95a' each have a head 101 having a diameter sufficient to close the hole 99 of the inlet member 97 or 98, respectively.

The fluid inlet pipe 48 is connected to the inlet above the central portion of the cylinder 96 so that the fluid can pass through the conduit 51 or 52, but at this time the movement of the valve change lever 72 Depending on whether the head of the piston rod moves from the inlet member, the conduit through which the fluid passes is determined, and the movement of the piston rod is controlled by the piston 95 or by contact with the valve conversion lever 72 that moves with the piston rod. Activate 95a.

The upper inlet (I.H.) is composed of a body (102) which can slide on a rod (103) built on a fixed column (104) fixed to a loom. A fluid spray injection nozzle 49 is installed in the body 102, and fluid conduits 51 and 52 are connected to the nozzle. Each injection nozzle 49 has holes 105 through which wefts P and P 'can pass, and fluid from conduits 51 and 52 flows into these holes 105. It is injected and propels the weft thread through the inclined S opening.

Assuming that 12 strands of weft P and 12 strands of weft P 'need to be inserted in order to actually form a pattern, the right injection nozzle 49 shown in FIGS. 4 and 5 is shown. You need to make) work. This means that the weft P and the fluid must be injected into the injection nozzle 97 and the fluid is supplied via the inlet member 97 and the conduit 51, and the lower supply furnace as shown in FIG. (11) means supplying the weft (P) while holding the weft (P).

Since the rollers 10, 11 are slid by the spring 30, no signal should be sent to the solenoid 33 in order for the weft P to be supplied to the nozzle 49. This state is shown in FIG. This is because there is no reflective tape under the photovoltaic cell 35 connected to the solenoid 33 as described above. The solenoid 33 receives no signal, but the solenoid 33a is excited because the reflective tape 41 passes through the photovoltaic cell 35a. Therefore, the rollers 10, 11 controlled by the solenoid 33a are isolated from each other, and the teeth of their small cogs 15, 16 are bitten with each other.

Therefore, the weft (P ') is not transmitted to the weft storage (S.E.).

When the shaft 56 rotates during weaving, the chain wheels 55 and 58 and the chain 57 move, thereby driving the selection cam 60. This causes the cam lever 62 to oscillate alternately around the shaft 63. The shaft lever 78 is in contact with the stopper 79. This is because the arm 75 is gripped by the spring 77 and the right nozzle 49 stays in a position suitable for insertion of the weft thread.

Since there is a reflective tape passing through the photovoltaic cell 36, the solenoid 89 is excited, so that the selection arm 84 is gripped at a position other than the path of motion of the cam lever 62, furthermore the arm. Since 83 is in the raised position, the capture element 66 is in the raised position with respect to the stopper 68.

The valve change lever 72 does not move in this way, and the selection valve inlet member 98 is left open because the head 101 of the piston rod 95a 'is gripped away from the end of the axial hole 99. Fluid injection is supplied through the injection nozzle, whereby the weft thread is inserted.

When the required 12 strands of weft are inserted, the solenoid 33 is excited when the tape 40 begins to pass through the photovoltaic cell 35, the roller 11 is separated from the roller 10 and the weft P is stored in the reservoir. No longer supplied to SE. At the same time, the end of the tape 41 passes through the photovoltaic cell 35a and the solenoid 33a is not excited, so the spring 30 moves the roller 11 toward the roller 10, thereby processing the weft yarn (P '). It is urgent.

The solenoid 89 is not excited because the tape 42 passes through the photovoltaic cell 36, and the leaf spring 94 moves the selection arm 84 downward so that the capture element 87 moves the cam lever 62. The dripping rod 83 is moved toward the arm 66 so that its recess 67 contacts the recess 81 of the shift lever arm 71a.

The cam lever is moved by the cam 60, and the recess 67 is in contact with the catching element 87 and snapped so that the cam follower 62 is separated from the cam. At the same time, the lever arm 71a moves to vibrate the shaft 63 and moves the arm 71 to move the valve change lever, thereby closing the inlet member 98 and opening the inlet member 97.

At the same time, the conversion rod 78 moves the upper end. Because arms 75 and 76 move. In this way, the upper inlet end is positioned so that the weft yarn P 'coming from the left nozzle can be inserted into the inclined opening by the fluid injection supplied through the selection valve inlet 97.

When the required number of strands of weft P 'is inserted, the cycle is resumed and weft P is fed back to its weft injection nozzle 49.

The weft yarn inserted twice is immersed by the body, and is cut by the weft cutter 44 in the vicinity of the injection nozzle.

As shown in FIG. 8, a shaft 200 is provided which has a pair of cams 201 (only one of which is shown) when only two weft yarns are inserted in a predetermined order. Each cam 201 controls the movement of a pair of rollers 10 and 11 through which a weft of yarn passes between them, and an arm mounted on the block 204 of the roller 11 for this purpose. At the end of 203, a cam follower 202 is built up. The block 204 is pivotally arranged in the portion 205 on the fixed block 206 on which the roller 10 is mounted. The block 204 is loaded by the spring 207 to bring the roller 11 into contact with the roller 10. As in the apparatus described above, the roller 10 is driven by the loom shaft 208 and the belt 209. The valve 209 winds up the pulley 210 on the shaft and also the pulley 211 on the roller shaft. There is a pair of small cog wheels 212, 213 so that the driving force can be transmitted to the rotor 11 in the manner described above. The other cam 201 has a similar cam trajectory, which serves to control the movement of the other roller 11 for another weft.

Since the cam 201 is built up on the shaft 200 so that the necessary movement of the roller 11 takes place at the same time, only one weft of yarn is supplied every time.

In connection with the operation of the rollers 10 and 11, a device is provided for adjusting the movement of the upper end and the gripping device.

This device is shown in FIG. As can be seen in the figure, the other cam 213 is laid out on the shaft 200.

The cam follower 214 abuts on the cam 213 and is disposed on the “T” type indictor 215, which is connected to the arm 215a of the indictment and the angle 215b. It is pivotally connected to. A link 216 is provided at the end of the arm 215a, which is connected to the conversion lever 217 with respect to the inlet end I.H. The lever 218 extending from the conversion lever 217 serves to move the upper inlet I.H. when the cam 213 rotates to move the lever 215. The angle 215b is connected by a link 219 to a gripper for activating the arm 220, so that when the cam 213 rotates, the arm 220 is in contact with either the gripper 221 or 222. Are aligned.

The gripping mechanism for operating the arm 220 is connected to the bell crank lever 223, which is pivotally connected to the fixing portion 224 of the loom, and the extreme of the lever arm 223a. There is a cam follower member 224a, which is moved by the cam 225, and each time the cam 225 rotates, the arm 220 moves under the holding mechanism 221 or 222 to place the thread. Supply to the mouth. In general, the gripping mechanisms 221 and 222 are subjected to a spring load for gripping the yarn. If necessary, instead of using the cams 201 and 213 to operate the mechanism, the arms 203 and 215 can be adjusted by means of a dobby mechanism via a link.

In the above two devices, the weft thread is guided by the driving roller from the source, and the weft gripping disks 24 and 25 continuously dissociate the weft thread every time the weft of the twelve rolls are inserted. When it is in place, the feed end is in the position where weft thread is inserted after the body needle is finished, and the weft cutter cuts the inserted weft thread from the source.

The fluid spray is adapted to operate simultaneously with the gripping mechanism, ie when the gripping mechanism is in a position where the weft can be fed through the nozzle. Since the weft yarn is continuously supplied to the storage mechanism by the continuous rotation of the driving roller, the weft yarn is gripped by the operation of the holding mechanism and the weft yarn is supplied to the storage mechanism for the next come while the inserted weft is cut. At the same time, the non-operating weft is gripped by the gripping mechanism, and the supply of the weft to the storage mechanism is stopped because the associated roller is isolated.

When it is necessary to insert another 12 weft yarn after inserting 12 weft yarns again, the program mechanism has a reflective strip of the same length or the cam has the same cam-track, so In the meantime, another tape or cam is actuated to intercept the surface of the drive to form the fabric. The fabric has twelve alternating stripes in width when two different weft threads are used.

Such streaks can cause even more change in the 24-ol safety organization. After inserting 23 colors of one color, insert the second color. At this time, if one color of one column is inserted and then 23 balls of a second color are inserted, the opposite pattern is obtained.

In addition to the addition of reflective tapes and photovoltaic cells to the programming facility, the addition of cams to the cap shaft, the use of more nozzles mounted on the upper end, more grippers and drive rollers, and more than two weft packages, two or more different Weft yarns can be inserted, thereby widening the range of permutations of the pattern.

If necessary, as many nozzles and weft feed mechanisms as necessary can be used to leave the weft-shaped space in the fabric. Reflective tape or cams are then used to permanently isolate the supply chain. Thus, only one pair of drive rollers and associated charges can be installed on a loom. In this case, if you select the program card or cam correctly and supply a lot of wefts of a certain weft and then stop the driving of the roller, there will be a weft-shaped space corresponding to a large number of wefts between the series of wefts inserted continuously. .

In the case of forming a heavier pellet (or the like) on the weft and simply injecting it through the inclined opening by a mechanical device (fluid device, if necessary), the gastric incidence described above is usually used. It is possible to propel the weft across the inclined opening by replacing it with a device similar to the drum needle (ie the head). At this time, of course, the head may be installed to be used simultaneously with the fluid injection propulsion device, and the device is provided with means for forming a pellet at the end of the weft yarn before inserting the weft yarn through the inclined opening. Such a device is advantageous when producing wide fabrics.

Instead of using photovoltaic cells or reflective tapes as programmers, slotted program cards and a series of detectors may be used.

Such a device is shown in FIG.

As shown, the detector tool 301 is in the form of a spring. It is fixed to the hard part 302 of the loom and is also connected to the anode lead 302a of the solenoid (for example solenoid 33). The program card 303 is endless, in which the grooves 304 are recessed at regular intervals in the longitudinal direction, the grooves of which are fixed to the card 39 by the reflective tapes in FIGS. 6 and 7. It is carved on the card 303 in the same format as that shown. The card passes between the detector port 301 and the series of magnets 305. The magnet 305 is connected to the cathode lead 305a of the solenoid.

When the card 303 arrives at a position where the detector port 301 can enter the groove 304, a circuit is formed to excite the solenoid. When the card 303 reaches the position where the detector port 301 will leave the groove 304, the circuit connected to the solenoid is broken.

Claims (1)

In a fluid spraying machine having two or more weft feeders and an IH, the one or more weft yarns are selectively disconnected by the folding of the weft feed drive rollers 10 and 11 for an incremental time period. In the meantime, a device consisting of a continuous drive cam 60 and a cam driven lever 62 for supplying the other weft to the upper end, and a program card on which the reflective tapes 40, 41, 42 or the groove 304 are mounted. 39, 303 with solenoids 33, 33a, 89 which are excited in accordance with signals generated when passing through the sensing devices 35, 35a, 36, 301. A fluid spray loom having at least one program device for controlling.

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