KR19990087207A - Moist yarn loom leads and weaving method using them - Google Patents

Abstract

In the state attached to the water weaving loom, a lead wing having a shape in which the upper part is bent to the right side in a "ku" shape, and when weaving using this lead wing, at least 100 twists or interlaces per 1 m as a warp. Friction with the warp caused by the fluctuation of the reed by bending the lead wing into the above-mentioned "u" shape using a warp consisting of a plurality of substantially lead-free thermoplastic synthetic fiber multifilament yarns having an entanglement point by processing. Weft insertion is made with water droplets into the inclined opening with the distance shortened.

Description

Moist yarn loom leads and weaving method using them

If the weaving speed of the loom (bookless) loom becomes high, it is naturally necessary to speed up the reciprocating motion of the lead. However, if the lead is to be reciprocated at high speed, a large inertia force acts on the lead. Therefore, in order to suppress the occurrence of inevitable vibration or the like caused by the generation of this inertial force, it is necessary to increase the rigidity of the lead or to reduce the weight.

Water jet looms that can be weeded along with the weft yarn by the jetting water, which can reduce the opening amount of the inclination, can reduce the lead height (the upper and lower dimensions), thereby making it possible to reduce the weight. It is advantageous in that it exists. On the other hand, air spray looms and rapier looms need to increase the opening amount of the inclination by the extent that the stability of the weft's non-column is low, thereby causing problems such as the vibration caused by the lead reciprocating. Becomes more serious. Therefore, in order to alleviate such a problem, in an air spray loom or a rapier loom having a large moving stroke of the lead, as shown in FIG. 1A, the upper part of the lead blade is bent to the immediately preceding side of the loom, thereby leading to a lead height. Attempts have been made to make (H; upper and lower dimensions) small and light. 1B is a sectional view of a lead in an air spray loom.

The advantage of lowering the lead height will be described in detail with reference to Fig. 1A which shows a state in which the opening angle α is formed by the lead wings 1 or 2, and the inclined 6 is opened up and down. . In the figure, when the lead blade 22 which was not bent to the front side shown by the dashed-dotted line and the lead blade 1 which was bent to the right side shown by the solid line is compared, it is understood that the following is obtained.

That is, in the linear lead blade 22, in order to open the inclined 6 up and down while forming the opening angle α, the lead height H 'becomes essential, whereas the upper portion is bent to the front side. In the lead blade 1 having a "" shape, it is good also as lead height (H). For this reason, the lead height can be made low, and the lead weight can be reduced.

However, as apparent from the geometrical relationship between the opening angle α of FIG. 1A and the bent lead blade 1 bent, the reduction effect of the lead height H is similar to that of the air spray loom or the rapier loom. Only when α) inevitably becomes large, it shows a great effect. However, when the opening amount of the inclination becomes small, that is, when the opening angle α is small, such as a water weaving machine, there is little effect, and an extra manufacturing step is required to bend the lead wing 1 to the front side. Even the undesirable side effect of increasing the manufacturing cost occurs. Therefore, in the water yarn loom, it was not considered at all to have a shape in which the lead blades were bent to the immediately preceding side.

In the lead of a water yarn loom operated at high speed, in order to avoid the problems caused by the above-mentioned rigidity shortage caused by the speed increase, the width of the lead wings must be widened or the thickness must be increased. On the other hand, on the other hand, if the thickness of the lead blade is increased, correspondingly, the gap through the inclination is inevitably narrowed. For this reason, the inclination causes a problem that the lead wing is easily rubbed and damaged, such as fluff, and the driving resistance of the lead is also increased. On the other hand, when the width of the lead blade is widened, water is retained in a larger amount due to capillary phenomenon (surface tension) between the lead blades placed side by side in the fate of the weaving loom using the weft inserting water. It is mentioned that the glue adhering to the warp melts due to the action of this large amount of water. If the grass falls by this action, or if the inclination of the grass that has missed the protective layer is rubbed, the inclination is more susceptible to damage, and it is natural to cause lint and the like easily because of this. In addition, when a large amount of water is maintained between the lead blades, there is also a problem that these water flows in accordance with the swing of the lead blades, causing vibration in the lead wings.

In addition, when weaving fabrics using multifilaments for warp yarns with a water yarn loom having a small opening amount of warp yarns, that is, a straight lead, it is conventionally used as a preventive means for preventing warp lint and warp breakage. A method of attaching a paste to a warp, a method of twisting a thread on a warp, and a method of tangling the warp have been adopted. Naturally, in weakly twisted yarns, filaments are broken because only some of the filaments of the filaments constituting the yarn are rubbed against the heald or the lead blades, as compared to the medium or strand yarns. This is likely to occur, and thus weaving becomes difficult. This is the same also in practically lead-free filament yarn provided with an interlacing point by interlacing. Therefore, on the weaving, the yarn of 500 to 3000 twists per minute and the number of twists per 1 m is hard to be fluffed, and in general, weaving can be performed without fixing the filament with a pull agent. On the other hand, the yarn of less than 500 twists per square meter of twisted yarn can be weaved relatively easily by fixing the filament with a glue, especially those having a relatively high twist count among the weak strands. On the other hand, among lead smokes, substantially no lead twists of less than 300 twists per meter and entanglement points by interlacing are practically lead-free multifilament yarns that are very difficult to weave, and also lead-free with no twist or entanglement points. Multifilament yarns are difficult to weave at a substantial speed.

In order to solve all the problems related to the lead of the conventional water-weaving loom described above, although there has been a long demand in the art, the fundamental solution has not been achieved.

In recent years, due to the diversification of textile products, in particular, in the polyester fiber fabrics that are frequently used in garments that require fashion, fabrics using thinner filaments and lead-free multifilament yarns are also required. . In the case of weaving such fabrics, 10 to 60 entanglement points per 1 m are formed in the lead-free yarn by interlacing, so that the filament is peeled off during weaving or only a part of the filaments are damaged by friction such as leads. Weaving is done while avoiding receiving. The interlacing point formed by interlacing is only loosened during weaving, and when all are woven, only a few interlacing points per meter remain, so that the same woven fabric as that using unleaded multifilament yarns can be woven. However, even if the above means are taken, it is very difficult to weave fabrics using such multifilament yarns with a water yarn loom, and the quality of the fabrics due to the breakage of the inclined filaments that are severely rubbed by the lead wings attached with water is difficult. There was a problem that a lot of stops due to a decrease in or a slope break occurred.

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a reed for a water yarn loom which is used when weft is accompanied by water flow injected from a nozzle attached to a water yarn loom, thereby inserting the weft yarn. Moreover, this invention relates to the weaving method of a thermoplastic synthetic fiber fabric using the said lead, More specifically, it has a point of intersection by a weak edge or an interlace process. The present invention relates to a method of weaving thermoplastic synthetic fiber fabrics inclined to multifilament yarns of substantially lead-free polyester and other thermoplastic synthetic fibers.

FIG. 1A is a side view for explaining the lead height H in a rapier loom and an air spray loom, and FIG. 1B is a side view of the lead blade in an air spray loom.

2 is a side view of a lead blade attached to a water yarn loom.

3 and 4 are side views illustrating the difference between the weaving method of the present invention and the conventional weaving method.

Figure 2 is a side view illustrating one embodiment of the embodiment of the invention for the yarn loom lead, according to the present invention, in which (1) is the lead wing, (2) the upper channel, (3) is the lead wing support Earth, 4 and 5 are the upper and lower coils, respectively, and 6 represents the slope, respectively. Here, the lid 10 for a water yarn loom of the present invention includes the lead wing 1, the upper channel 2, the lead wing support 3, the upper coil 4 and the lower coil (5). It is composed. In addition, the lead wing 1 is fixed at the upper end and the lower end by the upper channel 2 and the lead wing support 3, respectively, and adjacent lead wings are held at predetermined intervals for the passage of the inclination. As many as possible, the upper coil 4 and the lower coil 5 are installed in parallel in the direction perpendicular to the surface of FIG. 2. Moreover, the said lead blade 1 is in the state attached to the lead for water-weaving looms, has the shape which bend | folded the upper part in the "ku" shape to the front side immediately, and the depth of the upper side along the oblique insertion passage direction. The width is made narrower than the depth of the depth of the lower side. Moreover, the lower part of a lead blade is being fixed to the lead blade support tool 3 in the state which inclined the extension direction to the semi-right front side.

In addition, in the said figure, code | symbol (A), (B), and (C) represent the three positions which the same lead wing | blade 1 which fluctuates, drawing circular arc as shown by the code | symbol S at the time of weaving, takes. (A) is the position where the lead blade (1) is farthest from the immediately preceding side (the state of weft insertion by the jetting water from the water spray nozzle), (C) is the position nearest the front side (the warp yarn is inclined) (Beating state), and (B) show the state in the intermediate position with (A) and (C), respectively. From this figure, if the lead blade 1 oscillates while drawing an arc, it will be easily understood that the centrifugal force acts as an inertial force in the normal direction with respect to the arc.

In the lid of the water yarn loom constructed as described above, the characteristic of the lid of the present invention is that the upper part is bent in a "ku" shape to the front side (right side in FIG. 2) in the state where the lead blade 1 is attached to the lid. It is in what it is. Here, the definition of the " cube shape " can be said to be a state where the lead has a bend point above the point where the lead abuts immediately before, and the upper part of the lead is bent to the right side. And it is preferable that the position of this bending point exists in the range of 0.5 mm-20 mm, especially 0.7 mm-15 mm from immediately before. Moreover, it is preferable that a bending angle exists in the range of 20 degrees-45 degrees, especially 25 degrees-40 degrees.

On the other hand, the conventional lead blade only has a straight shape as shown by the dashed-dotted line of FIG. 1A, and it bends in a "ku" shape immediately to the front side, and measures the depth of the width of the lid wing on the upper side and the lower side. There is no exquisite window like the present invention about making cars.

Thus, the lead of this invention is employ | adopted instead of the conventional lead, based on the following knowledge of this inventor.

First, the inventors of the present invention, in the process of carefully reviewing the weaving speed of the water weaving loom, one of the major factors that hinders the speed of weaving is due to the fluctuation of the lead blade (arc motion), and in the conventional lead, It starts from knowing that the direction in which the inertia force (centrifugal force) acts with the water held at and the lead wing is caused to coincide with the extending direction upward in a straight line. In the conventional lead as described above, water held by capillary action (surface tension) between the lead blades 1 tries to move upward by centrifugal force. Since the upper channel 2 which blocks water exists, it was also found that the upper channel 2 prevents the movement of the water, so that the water retained between the lead blades cannot be blocked well. In addition, the water retained between the lead blades (1) melts the paste which becomes the protective layer of the inclined passage inserted between the lead blades, thereby imparting friction damage to the inclined, (2) the lead The water attached to the blade causes the weight to increase, and at the same time, the vibration of the lead is generated by the movement of the water (up and down along the lead wing) generated in accordance with the swing of the lead. And based on these knowledge, the lead of this invention was finally reached by studying the lead which can hold | maintain the water which hold | maintained between lead wings and staying well.

Knowing in detail the process and background from which the present invention described above is derived, it will be readily understood how much superior the lead of the present invention described below has in comparison with the conventional lead.

In other words, the lead vane 1 of the present invention has a shape in which a conventional lead vane extends straight in the same direction as the direction of action of the centrifugal force and has an upper channel blocking water in this extension direction. In the upper part, the upper part is bent to a "ku" shape immediately before, and this has an important role in water blocking. Here, the action regarding the water blocking of the lead blade 1 bent in this "cu" shape is the case where the centrifugal force acts on the water held in the lower part of the lead wing 1, and the water held in the upper part. It is easy to think of when dividing into two cases with the case where the centrifugal force acts.

That is, when the centrifugal force acts on the water held in the lower part of the lead wing 1 of the former, it is injected from the water spray nozzle (not shown) for the weft insertion at the position (A) of FIG. As a result, the water retained between the lead blades 1 receives centrifugal force due to swinging (arc motion) of the lid 10 and the lower part of the lead blades 1 moves along the extension upward direction. At this time, since the upper part of the lead wing 1 is bent in a "ku" shape to the front side immediately, there is no obstacle such as the upper channel 2 which serves to block water that is trying to move upward again from the bent part. Do not. For this reason, the water retained in the lower part of the lead blade 1 will be cut off from the lead wing at the bent part by centrifugal force as it is.

Next, when the centrifugal force acts on the water held on the upper part of the latter lead blade 1, in the present invention, the direction of action of the centrifugal force acting on the water according to the swing (arc motion) of the lid 10 is explained. And studying so that the extension direction of an upper part of a lead blade may play a very important role. That is, the water held by the lead blade 1 naturally moves in the normal direction (circular direction of the arc) of the trajectory (circular arc) to which the lead wing moves by centrifugal force acting on the water. In this case, when using a conventional lead that already has a lead wing in the direction of action of the centrifugal force acting on the water, the water simply moves upward along the lead wing and is blocked by the upper channel. The restraint on the wing is as described above. In other words, in order to prevent the water retained in the lead wing from remaining in the lead wing as it is, the direction of action of the centrifugal force and the extension direction of the lead wing must not coincide. Therefore, in the lead blade 1 of the present invention, a shape bent in a "ku" shape on the immediately preceding side is adopted, whereby water moves while being constrained to the lead wing 1 by surface tension with the lead wing 1. Direction and the direction of action of the centrifugal force are clearly different. By such a very sophisticated research, the water retained in the lead blade 1 is released from the restraint by the surface tension with the lead wing 1, and the rear edge of the lead wing 1 is inclined by the centrifugal force (inclination insertion direction). With respect to the edge of the opposite side).

Moreover, in the preferable aspect of the lead of this invention, the depth of the depth of the upper side of the lead blade 1 is narrower than the depth of the depth of the lower side along the diagonal insertion passage direction.

As a result, the water attached by the action of the surface tension (capillary action) to the lower side of the lead wing 1 is going to move from the lower side to the upper side under the influence of the centrifugal force, so that the depth of the depth of the eye decreases rapidly. It causes a drastic decrease in the adhesion force of the water to the generated lead blade (1). For this reason, the water adhering to the lead blade 1 is easily cut off from the lead wing 1 by the action of a centrifugal force, thereby reducing the amount of water held on the upper side.

In addition, when the circular arc of the lead blade 1 of FIG. 2 is drawn and oscillated, as is clear, since a force greater than the tip acts on the root (lower end) of the lead wing, high strength and rigidity are required. In the lid 10 of the present invention, in particular, the depth of the depth of the lower side of the lead wing 1 can be made wider than that of the upper side, and the strength and rigidity thereof can be sufficiently secured. Moreover, the depth of the depth of the upper side can be narrowed, the lead wing 1 can be reduced in weight, and eventually the lead itself can also be reduced in weight.

Moreover, in another preferable aspect of this invention, the extending direction of the lower part of the lead blade 1 is inclined to the semi-right front side, and the lower end of the said lead wing 1 is fixed to a lid wing support. With such a structure, since the front surface of the lid 10 is recessed in a "ku" shape when viewed from the immediately preceding side (part hatched in FIG. 2), the slope between the warp yarns and the weft yarns along with the jetted water is opened. When entering, it is possible to serve as a guide space for the weft yarn for smoothly judging the weft yarn with respect to the depression of the "ku" shape. It goes without saying that the stable weft insertion can be realized thereby.

Next, with reference to FIG. 3 and FIG. 4, the effect | action of the manufacturing method of the thermoplastic synthetic fiber fabric which used the said lead for a water weaving machine is demonstrated.

The method of the present invention utilizes a "ku" shaped lead as a means for preventing slanted lint or breaking off. Figure 3 is a schematic side view showing the difference between the weaving method of the present invention and the conventional weaving method using a straight lead. The lead 10 bent in a "ku" shape of the present invention is shown by a solid line, and the conventional straight lead 21 is shown by an imaginary line. In addition, the leads 10 and 21 are shown at both positions of the forward end position and the retreat end position, and the swing angle θ of the lead is the same as that of the conventional method.

The 1st characteristic by the weaving method of this invention is that the friction stroke S of the lead blade 1 with respect to the inclination 6 opened upward is made shorter much shorter than the friction stroke T at the time of the conventional method. You can do it. That is, by bending the upper portion of the lead blade 1 in a "ku" shape toward the immediately preceding 15 side, when the lead is retracted, the contact point 16 between the lead blade 1 and the inclined 6 is conventionally linear. Since the position where the lead wing abuts immediately before the contact point 23 can be closer than that of the contact point 23 when the upper lead blade 22 is used, the inclination 6 The friction stroke of the lead blade 1 can be made small, and the shortened portion is the tip side of the lead blade, that is, the portion where the lead blade rubs the inclination at a faster speed, and therefore, The damage caused by the warp can be reduced more than the friction stroke is shortened.

On the other hand, in the example of FIG. 3 in which the swing angle θ ₁ of the lead is the same, when the method of the present invention is used, the non-main passage of the weft yarn is narrowed by the area 17 in the oblique line in FIG. 3. However, since the flow of water conveying the weft yarn 18 diffuses into a circular area centered on the weft yarn, the area 17 obliquely shown in the drawing is originally classified as the classification 19 of water for weft conveyance and In the part which did not function so effectively as the path of the weft yarn 18, the reduction in the cross-sectional area of the weft path due to the bending of the lead blade 1 in a "ku" shape hardly prevents the weft insertion. On the contrary, since the weft passage becomes a shape close to the circular shape of the diffusion of water, the water droplets in the diffusion peripheral portion that do not contribute to the weft of the weft collide with the lead blade 1 and are scattered. It is rather effective for reducing the damage of the warp caused by the collision with the warp. That is, by bending the upper portion of the lead blade in a "ku" shape, water droplets which do not contribute to the conveyance of the weft yarn which is greatly spread upwards collide with the bent wing blades and are scattered, so that the water droplets having a large velocity are directly inclined. The second feature of the manufacturing method of the present invention is that the collision and the damage to the warp can be reduced.

The leading edge of the bent portion in which the lead blade is bent into a "ku" shape is an arcuate portion 20. The position that collides immediately before betting is set at a position slightly lower than the contact point 12 between the straight portion 11 below the leading edge of the lead blade and the arc-shaped portion 20. Thereby, the weft path at the time of inserting the weft yarn without changing the swing angle position of the sley sword can be made into a shape that surrounds the circular water of sorting by the "ku" shape of the lead blade 1. Can be.

Fig. 4 is a diagram showing that the above-described action of the present invention can be sufficiently exhibited even if the swing angle θ ₂ of the lead is larger than the swing angle θ ₁ in the conventional method. In this FIG. 4, while using the lead 10 provided with the lead blade 1 bent in a "ku" shape, the swing angle θ ₂ of the slaed mounted with the lead is determined by a conventional method. It is slightly larger than the swing angle θ _{1 in} the case. In this case, the decrease of the weft path 17 by bending the lead upward is compensated for by the increase of the weft path at the lower part of the lead wing by increasing the swing angle of the slaod, and the weft path than that shown in FIG. Can be made larger, thus making it easier to insert the weft. Also in this case, the friction stroke of the lead blade 1 against the inclination 6 above the opening can be made much smaller than the case where the linear lead blade 22 is used. As a result, the number of jets largely biased upward of the weft yarns 18 can be scattered by colliding with the upper portion of the lead blade bent in a "ku" shape, so that the same action as described in FIG. 6) damage can be greatly reduced.

In the case of the weaving method of the present invention, the water retained between the lead blades at the position below the bending point of the lead blade, i.e., the characteristic of the lead 10 having a "ku" shape, is the lead wing. According to the fluctuation of, the water retained between the reed blades is separated by the centrifugal force acting in the direction of arrow A in FIG. The third characteristic is that the amount can be further reduced, and the damage of the inclination caused by the inclination of the inclination traversing at high speed between the water held between the lead blades can be greatly reduced.

In addition, in the case of the method of the present invention, since the interference between the upper end of the lid 10 and the heald 14 is avoided, the interval between the heald 14 and the immediately preceding 15 can be made small, and the same The vertical movement stroke of the seed light necessary for obtaining the inclined opening angle can be made smaller than in the case of the conventional method, and also has the fourth feature that damage to the inclination can be made smaller.

Each of these characteristics is characterized by the fact that only a part of the filaments are damaged by friction with the lid 10 or the heald 14, or that the filaments are mutually intersected by crossing the water held between the collision of water droplets and the lead wings. By adopting the method of the present invention, since it works more effectively against the weakly multifilament yarns, which are easily scattered separately, and against the substantially unleaded multifilament yarns having interlaced points by interlacing processing having the same weaknesses, It is possible to weave thermoplastic synthetic fiber fabrics using substantially lead-free warp yarns having an interlaced point by weak or interlaced processing more easily and at high speed without damaging the warp yarns.

According to the weaving method of the present invention, since the crimping process is not performed on the weft yarn, the warp yarns of the weft yarns 18 in the non-pillar are less likely to be inclined, so that the inclined opening can be made smaller. Can be.

Hereinafter, an Example demonstrates this invention further more concretely.

An object of the present invention is to provide a lid for a water yarn weaving machine which has very little frictional damage due to the lead blades and which can realize stable and high speed weaving.

Another object of the present invention is to provide a weaving method capable of weaving thermoplastic synthetic fiber fabrics such as polyester yarns using multifilament yarns near lead-free more easily and at high speed.

According to the present invention, there is provided a lid for a water loom loom, which has a lead blade having a shape in which its upper part is bent to the right side in a "ku" shape in a state where it is attached to the lead for water loom looms. Is provided.

In addition, according to the present invention, by using the above lead, the inclination of a plurality of substantially lead-free thermoplastic synthetic fiber multifilament yarn having a twist point of 100 times or more per 1 m or an interlacing point by the interlacing process is used as the inclination. By using this method, the lead blade is bent into the above-mentioned " u " shape so that the weft is formed by water droplets in the inclined opening in a state in which the distance between the contact point between the lead wing and the inclination when the lead reaches the retreat end and immediately before. Weaving method is provided, characterized in that the insertion.

Example 1

Weaving test was carried out using a water weaving machine provided with a lead having a lead wing having the same shape as the lead wing illustrated in FIG. 2. At this time, the depth width of the lead blade 1 in the oblique insertion direction is 2.2 mm at the upper side and 3 mm at the lower side, and the adhesion density of the lead is 48 sheets / inch, and for forming the "ku" shape. The inclination angle of the upper half with respect to the lower half was 30 degrees. The contacting position of the lead front surface immediately before is set by setting 1 mm below the point where the arc (R portion) of the bent portion of the lead and the straight line of the lower half of the lead wing are in contact with each other.

In the weaving test using the apparatus described above, the interlace interlacing point of 50 denier / 24 fil as the warp is 30 pieces / m, and the lead-free, unleaded polyester filament yarn, and the substantially lead-free poly of 75 denier / 36 fil as the weft yarn. Using yarn of ester filament, taffeta fabrics were woven at 800 rpm. Here, in the present invention, as a factor capable of quantifying the effect, the number of stops (times / day / large) of the loom was given, and the number of stops (times / day / large) of the loom was examined (see Table 1). ).

Moreover, also about the conventional lead provided with the straight lead blade as a comparative example, other conditions other than a lead were made exactly the same as this Example 1, and the stop frequency (time / day / large) was investigated (Table | 1).

Comparative example Example Cause of slope 0.5 0.1 Weft 0.2 0.2 Cause of machine stop 2.1 0.4 Stop of other causes 0.6 0.5 Sum 3.4 1.2

As apparent from Table 1, when the lead of the present invention is used, it can be seen that the number of stops caused by the cause of the warp and the cause of the machine is greatly reduced as compared with the conventional lead. Moreover, when the cause of the stop due to the inclination was investigated in detail, it was found that the inclination was caused by the friction and breaking, and the effect of using the lead of the present invention was clear. In addition, as a result of examining the woven fabric after weaving, although not shown in Table 1, in the number of fluffs occurring in the warp clearly, in the present invention, compared with the conventional lead. In addition, when the contents are investigated in detail regarding the stop caused by the mechanical cause, the tip entanglement and the return of the weft of the weft inserted between the inclined openings are reduced, and the lead of the present invention is compared with the conventional one. It was found to be effective in the stability of the non-juju.

As described above, when the lead of the present invention is used, the water retained on the lead wing can be cut off very effectively, the weight of the lead can be reduced, and the water held on the lead wing is inclined. Even when the paste is adhered, the melting of the paste can be greatly controlled. For this reason, it is possible to reduce the weight of the lead, which sets the speed for speeding up the weaving of the water yarn loom, and at the same time, greatly reduces the occurrence of vibrations caused by the vertical movement of the water held by the lid wings. The melting of the inclined paste is drastically reduced, and the rubbing agent exhibits a very remarkable effect of rubbing on the lead blades and causing fluffing or single yarns to disappear.

In addition, by inclining and fixing the lower end of the lead wing to the lead wing support, it is possible to stably guide the non-weft of the weft during the weft insertion and to form a wider guide space, thereby realizing the stable weft insertion. Indicates.

Example 2

In a lead wing having the same shape as the lead wing illustrated in Fig. 2, a lead wing having an upper portion bent in a "ku" shape at 35 ° to the front side and having a lead wing having a narrower upper portion than the lower portion ( Density: 19 blades / cm), 50 de / 24 fil interlaced interlacing points of 25 decibels / m for warp, lead-free, unleaded polyester filament, and 75 de / 36 fil for substantially no lead Polyester filament was used to weave a polyester filament fabric having a weft density of 47 / in at a rotational speed of 750 rpm. At this time, the number of stops of the loom per unit is 24 hours a day, as shown in Table 2, and the effect of using the "ku" shape bending lead is large.

Bend lead Conventional lead Cause of slope 0.2 0.5 Weft 0.2 0.3 Cause of machine stop 0.6 1.8 Stop of other causes 0.4 0.5 Sum 1.4 3.1

Example 3

In the same manner as in Example 2, a lead (density: 18.5 wings / cm) having a lead wing having an upper portion bent in a "ku" shape at 33 ° to the front side and having a narrower upper portion than the lower portion was used. A polyacrylic glue was attached to a substantially unwoven polyester filament yarn having an interlacing point of 75 de / 72 fil at an inclination of 7 / m and having no twist other than the twist caused by A 75 f / 72 fil polyester filament yarn of the same type was used as the weft yarn, and a polyester filament fabric having a weft density of 50 / in was produced at a rotation speed of 700 rpm. The number of stops of the loom at this time is as shown in Table 3, and the number of stops of the loom can be greatly reduced as compared with when a normal lead is used.

Bend lead Conventional lead Cause of slope 0.3 0.4 Weft 0.3 0.3 Cause of machine stop 0.5 2.1 Stop of other causes 0.6 0.7 Sum 1.7 3.5

Example 4

In the same manner as in Example 2, a lead (18 blades / cm) having a lead wing bent in a "ku" shape at 30 ° to the front side immediately before was used, and 300 to nylon filament yarn 70 de / 108 fil as a warp. Twisting T / M and attaching 3.5% by weight of polyacrylic paste to the weft yarn, using 70 de / 108 fil lead-free nylon filament yarn of the same type, weaving 30 weft density at 900 rpm The nylon filament fabric of / in was woven. The number of stops of the loom at this time was as shown in Table 4, and the number of stops of the loom was greatly reduced compared to when using a normal lead. This is because the length by which the lead pulls the inclination is reduced by 7%, so that the occurrence of inclined lint is suppressed. In addition, during the jet jetted from the nozzle, jet jets other than jet jets required for conveying the wefts collide with the upper part of the bent lead, change into a fog shape, and touch the warp very smoothly. The classification that attracted the cartilage phenomenon was reduced, and the quality of the fabric was greatly improved.

Bend lead Conventional lead Cause of slope 0.3 0.9 Weft 0.2 0.2 Cause of machine stop 0.4 1.8 Other cause stop 0.6 0.7 Sum 1.5 3.6

According to the present invention, there is provided a lead for a water yarn weaving machine which is extremely low in inclination frictional damage due to lead blades, and which can realize stable and high speed weaving. In addition, the water yarn loom adopting such a lead makes it possible to weave thermoplastic synthetic fiber fabrics such as polyester yarns using multifilament yarns near lead-free more easily and at high speed. Big.

Claims (6)

A lid for water spray looms, comprising: a lead blade having a shape in which an upper portion thereof is bent to the front side in a "ku" shape in a state attached to a lead for water spray looms. The water | yarn loom lid of Claim 1 which made the width | variety of the depth of the upper side of the said lead blade along the diagonal insertion passage direction narrower than the depth of the depth of the lower side. The water loom lid according to claim 1 or 2, wherein the extension direction of the lower part of the lead blade is inclined toward the opposite side of the lead blade, and the lower end of the lead blade is fixed to the lid wing support. The lead wing using the lead of Claims 1-3 and using the inclination which consists of substantially lead-free thermoplastic synthetic fiber multifilament yarn which has the twisted point by 100 or more twists per 1m or interlacing as a warp | ramp. The composite is characterized in that the weft is inserted by the water droplets into the inclined opening in a state where the distance between the contact point between the lead wing and the inclination when the lead reaches the retreat end and the immediately before is bent by bending the square shape. Weaving method of textile fabrics. 5. The method of weaving a thermoplastic synthetic fiber fabric according to claim 4, wherein the weaving yarn is made to have a weaving speed of 550 rpm or more using a substantially lead-free thermoplastic synthetic fiber multifilament yarn that is not crimped. 6. The method of weaving a thermoplastic synthetic fiber fabric according to claim 4 or 5, wherein the warp yarn is a substantially lead-free, unleaded polyester multifilament yarn having an entanglement point of 10 to 60 interlacing per meter.