JP2006291414A - Method for producing braid and fishing line comprising the braid - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve physical properties of a braid by bringing difference in tension between a clockwise strand and a counterclockwise strand constituting the braid to be lessened. <P>SOLUTION: Two or more bobbins (6) are circulated around a circular track (10a) and a circular track (10b). Each bobbin (6) circulating around the one circular track (10a) is brought to pass outside and inside of the bobbin (6) circulating the other circular track (10b). Strands (7) drawn from the bobbins (6) are collected to a spinneret and assembled by interlacing to be a braid. The rotative direction of the bobbin (6) in drawing the strand (7) from the bobbin (6) circulating around the one circular track (10a) is brought to be different from that of the bobbin (6) in drawing the strand (7) from the bobbin (6) circulating around the other track (10b). <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a method for manufacturing braids used as fishing line and cords for racket guts, and the like, and more particularly to a fishing line made of braids. More specifically, the difference in tension between right-handed and left-handed strands constituting the braid is reduced. In addition, the present invention relates to a braid manufacturing method capable of improving the physical properties of the braid, and a fishing line capable of effectively utilizing the physical properties exhibited by the right-handed strand and the left-handed strand in a balanced manner.

A braid made by interlacing multiple strands can exhibit excellent physical properties such as high strength, strength and low elongation, so it is thin, such as fishing line, tennis racket gut, archery serving, etc. It is also used for codes.
These braids are generally manufactured using a string making machine. This stringing machine has clockwise and counterclockwise annular tracks, each of which has a plurality of bobbins mounted on a bobbin carrier and circulates around both of the annular tracks, and the bobbin that circulates around one annular track, It is configured to pass through the outside and inside of the bobbin that circulates the annular track. The braid is produced by assembling the strands taken from the bobbins while crossing them.

  The strands drawn from each of the bobbins described above are focused on a base located approximately at the center of the annular track in a plan view, for example. The annular track is meandering, for example, formed in a bowl shape so as to pass through the inside and outside of the other annular track, and the bobbin that circulates on the annular track has a distance from the base. The nearest short distance point and the farthest far point are alternately passed. Therefore, the bobbin carrier is provided with a tension device so that the strand does not loosen between the bobbin and the base.

  The tension device includes, for example, a weight loosely fitted to a payout bar arranged in parallel with the bobbin, a ratchet provided on the upper part of the bobbin, and an upper part of the payout bar above the weight. There is a thing provided with a nail lever fitted (for example, refer to patent documents 1). The strand pulled back from the bobbin passes through the through hole formed in the substantially central portion of the feeding rod and the through hole provided in the weight, and then passes through the guide hole provided in the upper portion of the feeding rod. Guided to the base.

  When the bobbin carrier goes around the annular track and approaches the short distance point, the strand is slackened, so the weight is lowered along the feeding rod, and a turn-up portion is formed in the strand feeding path. The above slack is absorbed. On the other hand, when the bobbin carrier moves away from the short distance point, the strand is pulled to raise the weight, and the absorbed slack is fed out from the guide hole. While the absorbed slack is drawn out, the pawl lever is engaged with the ratchet, so that the bobbin does not rotate by taking up the strand. During this time, a constant load is always applied to the strand by the weight, and a constant tension is applied.

However, when the above-mentioned slack is insufficient, the weight further rises and pushes up the claw lever, so that the claw lever is detached from the ratchet so that the bobbin can be rotated and the strand is unwound from the bobbin and taken up. At this time, since a strong tensile force is applied to the strand as much as the bobbin is rotated, the tension of the strand increases. The rotation of the bobbin due to the take-up of the strand occurs in the vicinity of the long distance point where the absorbed slack is easily insufficient.
When the strand is fed out by rewinding from the bobbin, the weight is lowered, the claw lever is engaged with the ratchet, and the rotation of the bobbin is stopped.

  On the other hand, in the annular track, the bobbin carrier passing through the vicinity of the farthest point farthest from the base and the bobbin placed thereon rotate in the rotating direction. When the rotation direction by this round coincides with the rotation direction by the above-mentioned strand take-up, it is necessary to turn the bobbin more quickly at the time of taking-up the strand, so that a strong tensile force is applied to the strand, and the strand The tension becomes higher. On the other hand, when the rotation direction by the round is different from the rotation direction by the take-up of the strand, the rotation by the take-up of the strand is offset with the rotation by the turn, the tensile force applied to the strand is weak, and the strand The increase in tension is suppressed.

JP-A-6-235152

  In the above conventional stringing machine, each bobbin that circulates in the clockwise and counterclockwise circular orbits employs a bobbin having the same structure, and from the ratchet structure provided on the top of this bobbin The bobbins that circulate in any of the annular tracks rotate in the same direction, that is, for example, counterclockwise (counterclockwise) in a plan view, so that the strands are drawn from the bobbins. For this reason, the direction of rotation of the bobbin that circulates around the circular track in the vicinity of the long distance point coincides with the direction of rotation of the bobbin by strand take-up in one circular track, and is different in the other circular track. It was. As a result, in the conventional braid manufacturing method, the tension is different between the right-handed strand and the left-handed strand constituting the braid, so that the so-called left and right balance is lost, and the strength and strength of the entire braid are reduced. There was a problem that it was not easy to improve physical properties such as elongation.

  For example, when using high-strength and low-strength strands such as fishing lines, if the tension or twist of each strand is different, some strands will not be able to receive the entire load evenly. When this load is received, it will stretch and break. As a result, there was a problem that the strength of each strand could not be used effectively as a whole fishing line, and the high strength obtained by adding up the strength of all the strands could not be sufficiently exhibited.

  An object of the present invention is to provide a method for manufacturing a braid that can solve the above-described problems and can reduce the difference in tension between the right-handed strand and the left-handed strand constituting the braid, thereby improving the physical properties of the braid. And it is providing the fishing line which consists of a braid which can utilize the physical property which a right-handed strand and a left-handed strand exhibit effectively in a good balance.

In order to solve the above-described problems, the present invention is described as follows, for example, based on FIGS. 1 to 6 showing an embodiment of the present invention.
That is, the present invention 1 relates to a braid manufacturing method, in which a plurality of bobbins (6) are circulated in a counterclockwise circular track (10a) and a clockwise circular track (10b), and one circular track (10a) is circulated. Each bobbin (6) to be passed is passed through the outside and inside of the bobbin (6) that goes around the other annular track (10b), so that the strands (7) taken from these bobbins (6) are interlaced. The method of manufacturing the braid is to assemble, and the rotational direction of the bobbin (6) when pulling the strand (7) from the bobbin (6) circulating around one annular track (10a) is changed to the other annular track ( It is characterized in that it is different from the rotating direction of the bobbin (6) when the strand (7) is pulled from the bobbin (6) that goes around 10b).

A bobbin that circulates around one annular track differs in rotation direction when it circulates in the vicinity of the far-distance point and a rotation direction when the strand is taken up from a bobbin that circulates around the other annular track.
For this reason, when the direction of rotation of the bobbin that circulates around one annular track coincides with the direction of rotation due to wrapping around the long distance point, the bobbin that circulates around the other annular track also The turning direction by the take-up coincides with the turning direction by the circulation in the vicinity of the long distance point. Also, when the direction of rotation of the bobbin that circulates in one annular track differs from the direction of rotation in the vicinity of the long-distance point, the bobbin that circulates in one annular track also takes up the strand in the bobbin that circulates in the other circular track. The direction of rotation is different from the direction of rotation caused by the rotation around the long distance point.
That is, the relation between the bobbin rotation direction by the rotation in the vicinity of the long distance point and the bobbin rotation direction by the strand take-up circulates the bobbin rotating around the clockwise circular track and the counterclockwise circular track. Matches with bobbin.

  Here, the turning direction of the bobbin when the strand is taken out from the bobbin can be made different from the rotating direction of the bobbin in the annular track. That is, from the bobbin that goes around the clockwise annular track, the strand is taken up by rewinding the bobbin so that it rotates counterclockwise, and from the bobbin that goes around the counterclockwise annular track, the bobbin rotates right. The strand is taken up by rewinding in the manner described above. Thereby, the pulling force for rotating the bobbin when pulling the strand can be reduced, and an increase in the tension of the strand can be suppressed, so that the occurrence of uneven tension in the strand constituting the braid is suppressed, which is more preferable.

  Further, the twist direction of the strand wound around the bobbin that circulates around one annular track can be made different from the twist direction of the strand wound around the bobbin that circulates around the other annular track. That is, each strand constituting the braid is twisted according to the direction of rotation by bobbin circulating around the circular track, but the twist direction of each strand of the bobbin rotating clockwise and bobbin rotating counterclockwise is set. By making it different, even if the twist by the above-mentioned rounding is applied to the strand, the right-handed strand and the left-handed strand are maintained at the same twist, which is more preferable.

  Further, the present invention 2 relates to a fishing line made of braided cords, in which a plurality of bobbins (6) are circulated in a counterclockwise annular track (10a) and a clockwise annular track (10b), respectively, and circulate around one annular track (10a). By passing each bobbin (6) through the outside and inside of the bobbin (6) circulating around the other annular track (10b), the strands (7) taken from these bobbins (6) are interlaced. A fishing line composed of assembled braids, the twisting direction of the strand (7a) wound around the bobbin (6) that goes around the one annular track (10a) and the bobbin that goes around the other annular track (10b) It is characterized in that it is different from the twist direction of the strand (7b) wound in (6).

In the above fishing line, the right-handed strand and the left-handed strand constituting the braid are maintained in the same twist with respect to the length direction (axial direction) of the braid. As a result, the strength exerted by each strand is effectively utilized, and the strength and strength of the entire fishing line is increased.
In particular, when the braid is assembled by the manufacturing method of the present invention 1, the difference in tension between the right-handed strand and the left-handed strand is reduced, and the balance between the left and right is further improved. The strength can be further increased.

  This fishing line is not limited to a specific material, but low elongation fibers such as ultrahigh molecular weight polyethylene fibers, aramid fibers, polyarylate fibers, polyparaphenylene benzobisoxazole (PBO) fibers, etc., having an elongation of 7% or less. When used, it is preferable because the strength of each strand can be used more effectively, and more preferably, it is applied to a fishing line using a low elongation fiber having an elongation of 5% or less.

  Since the present invention is configured and operates as described above, the following effects can be obtained.

  (1) In the first aspect of the present invention, the bobbin that circulates around one annular track is rotated around the other ring track in both the direction of rotation around the long distance point and the direction of rotation when pulling the strand. Therefore, the relationship between the bobbin rotation direction due to the rotation around the long distance point and the bobbin rotation direction due to the strand take-off is the relationship between the bobbin rotating around the clockwise circular track and the counterclockwise circular track. It matches with the bobbin that goes around. As a result, the difference in tension between the left-handed strand and the right-handed strand constituting the braid can be reduced, and a so-called balanced left and right braid can be manufactured, and physical properties such as strength, strength, and elongation of the entire braid can be improved. Can be improved.

  (2) In the present invention 2, the right-handed strand and the left-handed strand constituting the braid are maintained in the same twist with respect to the length direction (axial direction) of the braid, so that the strength exerted by each strand is effective. The strength and strength of the entire fishing line can be increased.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 5 show a string making machine used in the embodiment of the present invention, FIG. 1 is a schematic front view of the string making machine, FIG. 2 is a schematic plan view of the string making machine, and FIG. 3 is a partially broken bobbin carrier. 4 is a front view, FIG. 4 is an explanatory view of the bobbin operation, FIG. 4 (a) is an enlarged view of the main part in the vicinity of a long distance point in the counterclockwise annular track, and FIG. 4 (b) is a clockwise ring orbit. FIG. 5 is an enlarged view of a main part showing a schematic structure of a braid.

  As shown in FIG. 1, this stringing machine (2) for manufacturing a braid (1) has a plurality of bobbin carriers (5...) Movably mounted on an upper plate (4) of a drive unit (3). Each bobbin carrier (5) has a bobbin (6) mounted thereon. The strands (7) fed out from the bobbins (6) are focused on the base (8) disposed above and are assembled to the braid (1) by crossing each other. In addition, a core material (9) is supplied to the base (8) from below as shown by an imaginary line in FIG. 1, and strands (7...) Are interlaced around the core material (9). Also good.

  The strand (7) is made of, for example, high-strength fibers such as aramid fibers, ultrahigh molecular weight polyethylene fibers, PBO fibers, polyarylate fibers, synthetic fibers such as nylon fibers, polyester fibers, and fluororesin fibers, and inorganic fibers such as glass fibers. A multifilament or monofilament made of an arbitrary material such as a fiber can be used, and a linear body such as a metal wire can also be used. In addition, when using said fiber bundle, what twisted arbitrary twist numbers may be sufficient as this fiber bundle. In addition to the filaments, fiber bundles, and filaments, the core material (9) may be a braid prepared in advance.

  As shown in FIG. 2, two annular tracks (10) are formed on the upper plate (4). Each annular track (10) is provided with two bobbin carriers (5). One annular track (10a) has a bobbin carrier (5) orbiting counterclockwise in plan view and the other annular track. In (10b), the bobbin carrier (5) rotates clockwise. By this circulation, the strand (7) is drawn out from the bobbin (6) and taken up, and is focused on the base (8) disposed substantially in the center in plan view.

Each of the annular tracks (10) is formed in a bowl shape and meanders so that one annular track (10a) alternately passes outside and inside the other annular track (10b). Accordingly, the bobbin (6) orbiting the annular track (10) has a long-distance point (11) farthest from the base (8) and a short-distance point (12) closest to the base (8). ) And alternately.
In this embodiment, the above-mentioned annular track (10) has a bowl shape that passes through the outside and inside of the other annular track (10) twice, and each of the annular tracks (10) has two bobbin carriers (5). ), So-called four-strand braids are formed. However, in the present invention, the above-mentioned annular track may pass three times or more outside and inside the other annular track, and the number of bobbins may be made to circulate three or more times in each annular track.

  As shown in FIG. 3, the above-described bobbin carrier (5) has a guide portion (13) formed in a lower portion disposed in an annular track (10) formed in the upper plate (4). The upper plate (4) is held between the flange (14) and the lower flange (15). On the upper surface of the upper flange (14), a spindle (16) and a feeding rod (17) are erected in parallel with each other, and a bobbin (6) is fitted on the spindle (16).

The distance between the bobbin (6) and the base (8) is changed by circling the annular track (10). For this reason, the bobbin carrier (5) is provided with a tension device (18) so that the strand (7) does not loosen between the bobbin (6) and the base (8). The tension device (18) includes a weight (19) loosely fitted to the feeding rod (17) so as to be movable up and down, a ratchet (20) provided on the top of the bobbin (6), and a weight (19 ) And a claw lever (21) loosely fitted to the upper part of the feeding rod (17) above, and the claw portion (22) formed on the claw lever (21) is detached from the ratchet (20). It is locked as possible.
In this embodiment, the tension device using the weight of the weight is used. However, in the present invention, a tension device having another structure such as a tension device using the elastic force of a spring may be used instead. .

  The feeding rod (17) has a through hole (23) formed at a substantially central portion in the vertical direction, and a guide hole (24) provided at the upper end portion. The strand (7) fed out from the bobbin (6) passes through the through hole (23) and the hook portion (25) provided on the weight (19), and then the guide hole. It is guided to the base (8) through (24). As a result, the folded portion (26) is formed in the feeding path between the through hole (23) and the guide hole (24).

When the bobbin carrier (5) orbits the annular track (10) and approaches the short distance point (12) from the long distance point (11), the strand (7) is loosened. The weight (19) descends along the feeding rod (17), and the slack is absorbed by the folded portion (26). On the other hand, when the bobbin carrier (5) moves away from the short distance point (12) toward the long distance point (11), the strand (7) is pulled and the weight (19) rises and is absorbed. The slack is fed from the guide hole (24).
While the absorbed slack is sufficient, the pawl portion (22) of the pawl lever (21) is engaged with the ratchet (20), so that the bobbin (6) is in the strand (7). It does not rotate by taking over. For this reason, a constant load is always applied to the strand (7) by the weight (19), and a constant tension is applied.

  When the slack is insufficient due to the strand (7) being taken up, the weight (19) further rises and pushes up the claw lever (21) as shown by the phantom line in FIG. ) Is removed from the ratchet (20). As a result, the bobbin (6) can rotate, and the strand (7) is unwound from the bobbin (6) and taken up. When unwinding from the bobbin (6) occurs, the weight (19) is lowered, the claw lever (21) is lowered and the claw portion (22) is engaged with the ratchet (20). The rotation of 6) is stopped.

  When the strand (7) is rewound from the bobbin (6), a strong tensile force is applied to the strand (7) by the amount that the bobbin (6) is rotated, so that the tension of the strand (7) increases. . The rotation of the bobbin (6) due to the take-up of the strand (7) occurs in the vicinity of the long distance point (11) where the absorbed slack is easily insufficient.

  As shown in FIGS. 4 (a) and 4 (b), the bobbin carrier (5) passing through the vicinity of the long distance point (11) and the bobbin (6) mounted thereon rotate in the rotating direction. To do. On the other hand, the direction in which the bobbin (6) rotates when the strand (7) is taken up from the bobbin (6) and is rewound is set in the direction opposite to the above-described circumferential direction.

  That is, in the counterclockwise annular track (10a) shown in FIG. 4 (a), the strand (7) is taken up by rewinding the bobbin (6) so as to rotate clockwise. On the other hand, in the clockwise circular orbit (10b) shown in FIG. 4 (b), the strand (7) is taken up by rewinding the bobbin (6) so as to rotate counterclockwise. As a result, when the bobbin (6) is rotated and pulled, the tension of the strand (7) increases. The strand (7a) from the bobbin (6) that circulates around the left circular track (10a) and the right circular ring It becomes equal to the strand (7b) from the bobbin (6) that goes around the track (10b). Further, since the rotation of the bobbin (6) due to the take-up of each strand (7) cancels out the rotation due to the rotation of the bobbin (6), the tensile force applied to the strand (7) can be weakened, and each strand (7) The increase in tension is suppressed. As a result, it is possible to manufacture the braid (1) with the right and left balanced and with the occurrence of tension unevenness suppressed by the strand (7).

  The strand (7) wound around each bobbin (6) includes a bobbin (6) that circulates in the counterclockwise annular track (10a), and a bobbin (6) that circulates in the clockwise annular track (10b). The twist direction is reversed. That is, the strand (7a) supplied from the bobbin (6) that goes around the counterclockwise annular track (10a) is Z-twisted and supplied from the bobbin (6) that goes around the clockwise ring orbit (10b). The strand (7b) is S twisted. For this reason, as shown in FIG. 5, the left-handed strand (7a) and the right-handed strand (7b) are maintained in the same twist with respect to the axial center (1a) direction of the braid (1).

  Next, the twist of each strand and the winding direction to the bobbin were changed, the braid for fishing lines was assembled, and each strength was measured. The material of the strand used was ultra high molecular weight polyethylene fiber (Toyobo Co., Ltd., trade name: Dyneema) or polyarylate fiber (Kuraray Co., Ltd., trade name: Vectran), and the thickness of each strand was 110, 440, or 550 dtex, and the number of strands was 4 or 8.

Examples 1a-6a
The S-twisted yarn is wound around the clockwise bobbin so that the strand is taken up by rewinding the bobbin so that it rotates counterclockwise. The Z-twisted yarn is wound around the counterclockwise bobbin so that the bobbin rotates clockwise. The strands were wound so that the strands could be taken up.
Examples 1b-6b
An S-twisted yarn was used for the clockwise bobbin and a Z-twisted yarn was used for the counterclockwise bobbin, and the bobbin was wound so as to rotate counterclockwise so that the strand was taken up.
・ Comparative Examples 1-6
The Z-twisted yarn was wound around both the clockwise bobbin and the counterclockwise bobbin so that the strands could be taken up by rewinding the bobbin so as to rotate counterclockwise.

The comparison result of the strength of the braid assembled from each strand is shown in the comparison table of FIG.
As is apparent from this measurement result comparison table, the entire braid can be obtained by changing the twist direction of the right-handed strand and the twist direction of the left-handed strand in any type, thickness, and number of strands. Furthermore, the strength of the entire braid was further improved by making the rotation direction of the bobbin when taking the strand different between the clockwise bobbin and the counterclockwise bobbin. These improvements in strength were more remarkable when the strand thickness (single yarn decitex) was large.

  That is, when the thickness of each strand is 110 dtex, each of the comparative examples 1 using the same strand by changing the twist direction of the right-handed strand and the twist direction of the left-handed strand (Examples 1b to 3b) The strength is improved by 6.5 to 16.8% as compared to -3, and the rotation direction of the bobbin when taking up the strands is different between the clockwise bobbin and the counterclockwise bobbin (Example 1a- 3a) improved the strength 22.2 to 32.8% compared to Comparative Examples 1 to 3.

  On the other hand, when the thickness of each strand is 440 or 550 dtex, each comparison using the same strand is performed by making the twist direction of the right-handed strand different from the twist direction of the left-handed strand (Examples 4b to 6b). The strength is improved by 22.7 to 28.4% compared to Examples 4 to 6, and the bobbin rotating direction when taking up the strands is different between the clockwise bobbin and the counterclockwise bobbin (Example) 4a-6a) improved the strength 40.9-60.0% compared to Comparative Examples 4-6, respectively.

The method for manufacturing the braid described in the above embodiments and examples is illustrated in order to embody the technical idea of the present invention, and the method of the present invention is not limited to this embodiment. Various modifications can be made within the scope of the claims of the invention.
In addition, the string making machine used in the above embodiment is also exemplified for the number of bobbin carriers and bobbins, the shape of the annular track, the structure of the tension device, etc., and is not limited to those of these embodiments. Furthermore, the thickness, material, presence / absence of core material, type of core material, cross-sectional shape of the braid, and the like are appropriately selected and set according to the purpose of the braid.

  The present invention can improve the physical properties of the braid by reducing the difference in tension between the right-handed strand and the left-handed strand constituting the braid, and is particularly suitable for the production of guts such as fishing lines and tennis rackets, and archery serving. However, it is also suitable for manufacturing braids for other uses.

It is a schematic front view of the stringing machine used for embodiment of this invention. It is a schematic plan view of a string making machine. It is a partially broken front view of a bobbin carrier. FIG. 4 (a) is an enlarged view of the main part in the vicinity of the long distance point on the counterclockwise circular orbit, and FIG. 4 (b) is a diagram in the vicinity of the long distance point on the clockwise ring orbit. FIG. It is a principal part enlarged view which shows schematic structure of a braid. It is a measurement result comparison table of the strength of a braid using various strands.

Explanation of symbols

1 ... braid 6 ... bobbin 7 ... strand
7a… Left-handed strand
7b ... right-handed strand
10 ... circular orbit
10a ... counterclockwise circular orbit
10b ... clockwise circular orbit

Claims (6)

A plurality of bobbins (6) circulate in the counterclockwise annular track (10a) and the clockwise annular track (10b), and each bobbin (6) that circulates in one annular track (10a) is connected to the other annular track. (10b) is a method for manufacturing a braid, in which the strands (7) taken from these bobbins (6) are crossed and assembled by passing the bobbins (6) around and around the bobbins (6).
The direction of rotation of the bobbin (6) when pulling the strand (7) from the bobbin (6) that circulates around one annular track (10a), and the strand from the bobbin (6) that circulates around the other annular track (10b) ( 7) A method for manufacturing a braid, characterized in that the bobbin (6) is moved in a direction different from that of the bobbin (6).   The rotation direction of the bobbin (6) when pulling the strand (7) from the bobbin (6) circulating around each annular track (10) is different from the rotating direction of the annular track (10). Item 2. A method for producing a braid according to Item 1.   The strand (7b) wound around the bobbin (6b) around the other annular track (10b) is twisted in the twisting direction of the strand (7a) wound around the bobbin (6) around the one annular track (10a). The manufacturing method of the braid of Claim 1 or Claim 2 made different from the twist direction of). A plurality of bobbins (6) circulate in the counterclockwise annular track (10a) and the clockwise annular track (10b), and each bobbin (6) that circulates in one annular track (10a) (10b) is a fishing line composed of braids that are assembled by crossing strands (7) taken from these bobbins (6) by passing them through the outside and inside of the bobbin (6) that circulates,
The strand (7b) wound around the bobbin (6b) around the other annular track (10b) is twisted in the twisting direction of the strand (7a) wound around the bobbin (6) around the one annular track (10a). ) A fishing line made of braid, characterized in that it is different from the twisting direction.   A fishing line comprising the braid according to claim 4 assembled by the manufacturing method according to claim 1 or 2. The fishing line comprising the braid according to claim 4 or 5, wherein the strand (7) is a low elongation fiber having an elongation of 7% or less.

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