CS223990B2 - Method of coating the weft thread in pneumatic loom and device for executing the same - Google Patents

Abstract

A main compressed-air jet nozzle (3) blows the weft thread (1) into a guide channel penetrating into a shed and consisting of slotted rings (7) arranged next to one another, from where it is then carried further into the warp shed (10) by air jets from a multiplicity of auxiliary nozzles (13a to 13i). At the same time, the conveying force of the air jets issuing from the auxiliary nozzles increases at an increasing distance from the main nozzle, in that the quantity of air issuing from the individual auxiliary nozzles is increased correspondingly. As a result, the consumption of compressed air can be reduced, whilst the highest possible efficiency is ensured. <IMAGE>

Description

BACKGROUND OF THE INVENTION The present invention relates to a method for introducing a weft yarn in a pneumatic state, wherein the weft yarn is ejected through the main nozzle by an air jet and is guided through a guide channel to engage the shed with air jets blown from a plurality of auxiliary nozzles.

In pneumatic nozzle states, the weft is thrown into the shed by compressed air flowing out of the main nozzle and carried by the air jets from the auxiliary nozzles on the path in the guide vane channel. To this end, at a particular point in the duty cycle of the condition, a plurality of auxiliary nozzles can be embedded in the shed to support the weft entrainment and maintain its speed. When the front end of the weft thread projected by the main nozzle and moving through the shed> approaches or reaches one of the auxiliary nozzles, the auxiliary nozzle blows a jet of air which forces the weft thread forward; when the front end of the weft thread passes through the auxiliary nozzle, the air jet blowing is interrupted. Thereafter, the air blower takes on the next nozzle, the air jet of which carries the weft thread further through the shed to the next auxiliary nozzle.

The weft is thus gradually carried by the auxiliary nozzles lying in the shed in the direction of the weft yarn movement in succession to the range end.

When the amount of air blown from each auxiliary nozzle is the same and constant, there are some difficulties in picking: as the weft moves through the shed, the length of the weft yarn and thus its weight increases, so the auxiliary nozzles near the shed end should have more entrainment. force than the auxiliary nozzles located at the inlet side of the shed. However, since the amount of air exiting each auxiliary nozzle is the same, the entrainment force exerted by each auxiliary nozzle is the same. Therefore, when the amount of air is adjusted to suit the auxiliary nozzles located near the main nozzle, the nozzles on the shed exit side do not have sufficient force to carry the weft yarn with sufficient tension, cannot straighten it, and cannot apply a certain tension. This results in defects in the fabric being fabricated. Conversely, when the amount of blown air is adjusted to suit the auxiliary nozzles located at the outlet side of the shed, to eliminate this deficiency, the auxiliary nozzles near the inlet side of the shed diminish unnecessarily large amounts of air, thereby generating large compressed air losses.

The method according to the invention removes these drawbacks and consists in that the force generated by the jet of air from the auxiliary nozzles is gradually increased according to the distance between the main nozzle and the respective auxiliary nozzle. the proportion of the distance between the main nozzle and the respective auxiliary nozzle · In the periodic vaporization of air from the · auxiliary nozzles, according to the invention, the dwell intervals are controlled so that the auxiliary nozzles vaporize the air streams in the order in which the weft thread approaches is carried out in such a way that air is dimmed from the main nozzle and, from the first group of auxiliary nozzles, then the weft yarn engages in the retention device, the air jets from the second group of auxiliary nozzles are vaporized and then the air jets from the third group of auxiliary nozzles ch nozzles.

The invention also relates to a weft yarn insertion device comprising a main weft yarn nozzle through the air blown from the main nozzle, a lamella forming a guide channel through which the weft yarn passes from the main nozzle to the shed, and a plurality of jet nozzles each provided with a jet nozzle. According to the invention, the device is provided with a device for gradually increasing the force exerted by the air blown from the auxiliary nozzles in dependence on the distance between the main nozzle and the respective auxiliary nozzle, in particular a device for gradually increasing the reduced air of the blown air. by auxiliary nozzles depending on the distance between the main nozzle and the respective auxiliary nozzle. Auxiliary nozzles themselves can be used for this purpose, the nozzle opening diameters gradually being obtained. according to the distance between the main nozzle and each respective auxiliary nozzle. _t

The auxiliary nozzles are connected to a device for controlling the air vapor intervals causing the air jet to be vaporized from the auxiliary nozzles in the order in which the weft thread approaches the auxiliary nozzles. At the same time, the auxiliary nozzles grouped in groups of 3 mm in each group have the same nozzle orifice diameter and the nozzle orifice diameters of the individual auxiliary nozzle groups gradually increase as the distance between the main nozzle and the respective auxiliary nozzle group increases. .

When weft yarn is wiped out with the help of additional air jets with gradually increasing force, the weft is constantly straightened during the weft and its forward end does not lose speed. At the same time, a considerable saving of the compressed air blown from both the auxiliary nozzles and the main nozzle is achieved. .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of the weft picking device of the present invention; FIG. 2 is an enlarged view of a portion of the guide channel of FIG. 1 and FIG. 3 is a sequence of operations in the apparatus of FIG. 1.

According to FIGS. 1 and 2, in the pneumatic nozzle state, the weft thread X is thrown by the main nozzle

3. a worn lamella comb consisting of a series of slats χ forming more than 6. 6. The weft yarn X enters the main nozzle J after passing through the retention device 2, which is able to catch the weft yarn X if necessary so that it cannot enter the main the nozzles are fixed at a certain distance in a row and their feet are encapsulated with solidified resin or plastic X, so that the lamellas X are fixed immovably in the groove of the holder 8, the holder 8 is fixed on the bidlen 2 carrying the spoke 6, so that the lamellae X, the bidlen 2 and the beam 6 form one piece. Each lamella X has a generally circular picking opening 7a and a threading gap 7b. which allows the weft yarn X to be removed from the picking hole 7a. The passage opening 7a of the successive lamellae J forms the guide channel 6. The lamellas 2 are positioned such that the axis of the main nozzle J passes through the guide channel 6 as soon as the beam 4 lies in its most proximate position. Also shown in FIG. 1 is the warp yarn assembly 10 and the edge 11 of the fabric 52.

The calling channel 6 further comprises a plurality of auxiliary nozzles 13a to 133 which are arranged in a row parallel to the picking direction and substantially equidistant from one another. The body of each auxiliary nozzle 13a to 13i is formed by a metal tube, for example having a cross-section of 7 mm, the lower part of which passes through the lower section of the holder 8 so that it is fixed therein by resin or plastic. Each auxiliary nozzle 13a to 13i is located between the two slats 6 and its upper end lies close to the outer periphery of the guide channel 6 limited by picking holes 7a of the slats. The upper end of each auxiliary nozzle 13a to 13i is closed and its outer surface has a smooth rounded shape so that the auxiliary nozzles 13a to 13i, when nested in the shed, can easily penetrate between the warp yarns 10 and push them away.

At the upper ends of the auxiliary nozzles 13a to 13i, a nozzle opening 14a to 14i is formed in their cylindrical wall. 2 of which only the nozzle openings 14a are shown. 14b. 14c. Each nozzle hole 14a to 14i and 13a of the auxiliary nozzle 131 is - formed so that its axis is not parallel with the axis of the guide channel 6, but intersects the axis of the guide channel or -6-axis principal tr ^y s ^ky 2, and it forms about ^{1 diagonals} el 5 ^{<° -} ta ^ ed ^my C ^d mod ^hook lugs on the surface of each lamella vni.tiřOií 2 forming an insertion hole 7a.

In a specific example embodiment, the TR ^y-profit otvpry 14a to 14c of the first group - pomociých nozzles 13a to 13c formed with a diameter of 0.8 mm; tr ^y-profit holes 14d to 14f of the second group pomoccých nozzles 13d to 13f mmaí diameter of 1.0 mm, and the nozzle openings 14 g to 141 of the third group of nozzles pomoccých 13 g to 13i mmaí diameter of 1.2 mm. Thus, the diameters of the nozzle openings 14a to 14i gradually increase as their position approaches the outlet side of the shed.

The bottom of each auxiliary nozzle 13a to 13i extends downwardly - from the lower surface of the spar, as shown in FIG. 2. The lower ends of the auxiliary nozzles 13a to 13a. 13i are connected to the hoses ^15a-1, not shown 5i aid ^of fastening NYCHA PRVT, e.g. -t ^ niHch ^P with ^age, so that their concentration was airtight. Air distributors 16a to 16c are located below the fabric 12 to be produced.

attached to a beam (not shown) mounted on the nozzle frame on both sides. Each air distributor 16a to 16c is provided with three outlets (not shown); the three outlet openings of the air distributor 16a are interconnected by a heater. 15a to 15c with auxiliary nozzles 13a to 13c. the air holes in the air distributor 16b are connected by hoses

15d to 15f with auxiliary nozzles 13d to 13f. and three air vents in the air distributor

16c are connected by hoses 15g-15i to the power nozzles 13g-13. The air holes of each air distributor 16a are not shown. 16b. 16c are connected by pipes 17a to 17c to valves 18a to 18c. which are mounted on said beam. The air inlets of the veins 18a to 18c are connected via a duct 19a to 19c to an air tube 20 which is closed at one end and connected to an air source (not shown), e.g. a compressor. The air oven 20 may be directly connected to the bag air source for the main nozzle.

Each of the veenils 18a to 18e is formed so that it can be opened and closed and thus allows and closes the air supply from the air tube 20 to one of the auxiliary nozzles Ua to 13i. 21b or 21c, one end of which is pivotally mounted on the veenil body 18a to 18c. A roller 22a..22b is rotatably attached to the other end of each swing arm 21a to 21c. 22c. The swinging arms 21a to 21c are biased by a spring (not shown) in the sense of closing the material 18a to 18c. so that they are elastically attracted to the circumference of the cams 24a. 24b. 24c. The cams 24a to 24c are mounted on a rotating shaft 22 which rotates at a predetermined time dependence on the duty cycle of the state. Each cam -24a to 24c - has a cam projection 25a to 25c and a cam depression 26e to 26c. The cams are rotated so that the cams 25a. 25b. 25c is dropped - У1рНЛпУ 22a. 22b. 22c, respectively. The contact of the cam-like projections 25a. 25b. 25c with tips 22a. 22b. 22c results in pivoting of the swing arm 21a. 21c against the force of the spring (hence the opening)

223990 '4 valves 18a through. 18c. 1 and 2 will be explained with reference to FIG. 3.

Until ^W ORK · cycle condition nedosátae about 1 ²⁰ ° ^C o beating introduced útkzové aprskem yarn ^P '· £, refers to j. all rollers 22a. 22b. 22c veenils 18a. 18b. 18c of the cam depressions 26a. 26b. 26 <p. so that all veently 18a to 18c remain closed, which is the position shown in Fig. 1.

^Kd Y ^{Z W} ORK cycle condition ^d osáhne _ 120 come outpu cam 25a ek ^p va ^{CKY 24} and the contact ^d. by 22a. thus opening veenil 18a. As a result, the air from the air tube 20 is added through the duct 12a. veetíl 18a. tube 17a. an air distributor 16a into hoses 15a to 15c. so that the compressed air flows through the nozzle openings 14a-16 and the auxiliary nozzles 13a-13c. When the loom operational cycle reaches about 125 ^Ο> · release the retainer 2 ^ú Numeric thread. £ which is entrained with the air ^With ENA dýmaným of assistance ACTIVE nozzles 13a to 13c, and simultaneously drawing air from the main nozzle J. It is evident that although the diameters of the nozzle openings 14a to 14c of auxiliary nozzles 13a to U.S. are small, so that the breathing air is mnoasví Maxey sufficient tension force is generated to move the weft yarn. At the same time, a considerable amount of such air is saved, since the length of the weft yarn carried by the first group of auxiliary nozzles 13a to 13c is relatively short.

When ^{f W} ORK Navua cycle reaches about O ⁰ ^ p ^ ^s e I.V. front end ^of thread ^ú Numeric £ proximity to auxiliary. nozzles 13c. At this point, the cam projection 25b contacts the cam 24b of the follower 22b. So that verntl 18b opens; consequently, the compressed air and the auxiliary nozzles 13d to 13f are blown through their nozzle holes 14d to 144f. The front end of the weft yarn 8 is thus entrained by the air vaporized from the auxiliary nozzles 13d to 13f. Since the diameter of the nozzle openings 14d to the auxiliary nozzles 13d to 13f is larger than the diameter of the nozzle openings 14a to 13f.

14c. is the plural of the breathable air is greater so that the entrainment of the weft thread, which has at this location a greater length and hence more hmoonoot is s ^ ^{<^}} ^ oe ly provided. When the loom operational cycle Osáhne about ¹ ^ ^0, ^ CKA goes down KLA vennilu ²² and ¹⁸ and into wolves proMubně ²⁶ and VA ^{CKY 2} 4a. so that the air supply to the auxiliary nozzles 13a to 33c is stopped.

^The duty cycle Y ^Z state DCS ^Ah LV about 2 ⁰ 0 ^{o d} e ^d drawbar severed thread end ^at Numeric £ clogging. Do shed nearby! auxiliary nozzles 13f. At this point, the cam projection 25c of the cam 24c comes into contact with the pusher 22c. thereby opening the valve 18c. As a result, the pressurized air flows from the nozzle openings 14g to 14i through the auxiliary nozzles 13я to £ 31i. The diameter of the thrust holes 14c to 14i of the auxiliary nozzles 13g to LU is greater than the diameter of the thrust holes 14d to 14f of the auxiliary nozzles 13d to 13f, and hence the amount of air is greater than the air. so that the strength of the weft undamaged is increased. Consequently £ weft thread, whose length and thus the haoonost zvěěšila ^UC inne and ^p env ^of entrained ^With ENA ^d in a measuring channel in the sixth ^Kd Y ^{Z W} ORK cycle state is reached about ²¹ ° 0 Mozartstadt follower 22b to 18b vennilu cam depressions .26b of cam 24b. thereby closing vernt 18b and stopping air breathing from the auxiliary nozzles 13d to 13f. Thereafter, the breathing of air from the main nozzle J is also interrupted. The pull on the weft yarn is then exerted by the inertial force of the weft yarn itself and by the force of the air breathing through the auxiliary nozzles 13g to 13i. thereby completing the weft yarn insertion through the guide channel 6.

^The dy ^ ^F ^^ acovní trot condition ^ Sato about ² 30 ^O is. The insertion device is closed, thereby interrupting the movement of the weft yarn. At the same time, the follower 22c slides the valve 18c into the cam recess 26c, thereby closing the valve 18c. so that the compressed air is interrupted by the auxiliary nozzles 13g to 13i. When the slats X are pulled out of the shed by the forward movement of the spoke 6, the weft thread 8 slips out of the sliver 7b from each slat χ. Then, the weft T ni ^ .. £ assigning ^p and ^p £ rskem to ^tk Anino ^'12 ^ ^p lodges RLC ^c vníhc cycle state odpipoídda ^ i ^{3 O} 66.

Although it has been assumed in pqss that the auxiliary nozzles 13a to 13i are divided into three groups, where the diameter of the nozzle openings of the individual groups is different. It is evident that the nozzle orifice diameters of all the auxiliary nozzles may be relative to one another and may gradually increase according to the distance of the auxiliary nozzles from the main nozzle J.

In the embodiment described, the auxiliary nozzles 13a to 13i are generally designed such that the air escapes therefrom at the speed of sound, so that the amount of breathing air remains unchanged even if the pressure of the air supplied to the auxiliary nozzles varies. However, when it is sufficient for the weft yarn to pass properly that the air exits the auxiliary nozzles at a speed lower than the sound velocity, the rate of breathing air from the auxiliary nozzles can be controlled by varying the pressure of the air supplied to each auxiliary nozzle. . .

Although the principle of the invention has been described in conjunction with a pneumaaic condition, the slats of which almost completely surround and close the guide channel 6, with the exception of the exit gap 25, of course that the principle of the invention is also applicable to other types of pneumaic conditions. it surrounds only three-quarters of the circumference of the guide channel, one quarter of which is therefore open, and with a large number of auxiliary nozzles positioned along the guide channel, where air breathing from the main nozzle only serves to exert a pushing motion on the weft yarn serves the air breathed from the auxiliary nozzles. Even in this case, the principle of the invention allows better and even better insertion of the weft into the shed.

It is also self-evident that the principle of the invention is also applicable in a pneumatic state of the type wherein the shed weft is shed mainly by the action of an air jet breathing from the insertion or main nozzle and supported by air jets from the auxiliary nozzles located between the lamellas. especially suitable for weaving wide fabrics.

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Accordingly, according to the invention, the force exerted by the air breathing from the auxiliary nozzles gradually increases at a distance between the insertion or main nozzle and the auxiliary auxiliary nozzle. Thus, although the weft yarn's fouling increases with the picking process, the leading end of the weft yarn is pulled with sufficient force to allow the entire weft yarn to pass through the guide channel so that the entire weft is straight and has sufficient tension. This not only contributes to the quality of the fabric being fabricated, but also to the saving of air breathed from the auxiliary nozzles and thus to the reduction of the consumption of such air.

Claims (9)

A method of clogging a weft yarn in a post-alealic state, wherein the weft yarn is ejected by a main jet through an air jet and is guided through a guide channel to be entrained into the shed by air jets breathing from a plurality of auxiliary jets. a jet of air from the auxiliary nozzles according to the distance between the nozzle and the auxiliary nozzle. 2. Method according to claim 1, characterized in that, in order to gradually increase the force, the amount of air breathed by the auxiliary nozzles is gradually increased according to the distance between the main nozzle and the respective auxiliary nozzle. 3. A method according to claim 2, characterized in that the air breathing intervals from the auxiliary nozzles are controlled so that the auxiliary nozzles blow the air streams in the order in which the weft thread approaches. 4. Method according to claim 3, characterized in that the interval control is carried out in such a way that: the air is breathing from the main nozzle and the first group of auxiliary nozzles, releasing the engagement of the weft yarn in the retention device, breathing air jets from the second group of auxiliary nozzles, and then air jets from the third group of auxiliary nozzles. 5. Apparatus for carrying out the method of item 1, comprising a main weft yarn nozzle by air blown from the main nozzle, a lamella forming a guide channel through which the weft yarn passes from the main nozzle to the shed, and a plurality of auxiliary nozzles each provided with a nozzle an orifice for blowing the weft yarn through the guide channel, characterized in that it is provided with a device for gradually increasing the force exerted by the air blown from the auxiliary nozzles (13a to 13), depending on the distance between the main nozzle (3) and the respective ratio. nozzle (13a to 13). 6. Apparatus according to claim 5, characterized in that the means for gradually increasing the force consists of a means for gradually increasing the amount of air breathing by the auxiliary nozzles (13a to 131) over a distance between the main nozzle (3) and the auxiliary nozzle (13a to 13). ) ♦ Apparatus according to claim 6, characterized in that the device for gradually increasing the amount of air is formed by auxiliary nozzles (13a to 13i), the diameters of the nozzle openings (14a to 14i) being gradually increased according to the height. meei main nozzle (3) and each associated auxiliary nozzle (13a to 13i) · Apparatus according to claim 7, characterized in that the auxiliary nozzles (13a to 13i) are connected to a device (23, 24a, 24b, 24c) for controlling the air-blowing intervals causing the air jet to breathe from the auxiliary nozzles (13a to 131), respectively. in which the weft thread (1) approaches the auxiliary nozzles. Apparatus according to claim 6, characterized in that the auxiliary nozzles (13a to 131) grouped in groups of three each have the same nozzle aperture diameter (14a to 14i) in each ski, the nozzle aperture diameters (14a to 141). The single groups of auxiliary nozzles (13a to 13) increase in succession as the distance between the main nozzle (3) and the auxiliary nozzle group (13a to 13i) increases.