DE602005000983T2 - Device for producing a fancy yarn - Google Patents

Description

BACKGROUND OF THE INVENTION

1. Field of the invention

The The present invention relates to an apparatus for manufacturing of special yarn, and in particular a device for manufacturing (Spiders) of special yarn that is called flame yarn or fancy Garn is called, whose thickness is not constant, but varies.

2. Description of the stand of the technique

So far, there was special yarn, which is referred to as a flame yarn or unusual yarn whose thickness is not constant and which is partially made thick. As in 2 is shown, special yarn (flame yarn) SY is prepared so that the thickness of a thick point (thick yarn section) (thick layer thickness D), length (thick spot length L) and interval (distance P between thick places) each vary. A fine spinning machine used in the case of manufacturing such special yarn has the same main structure as a fine ring spinning machine. In the fine spinning machine, a front roller and a rear roller in a stretching area (stretching device) can be independently driven by a speed change. As an apparatus for producing special yarn, there has been proposed an apparatus including: a driving device that is driven by at least one of a front roller system and a rear roller system of a fine spinning machine by means of a variable speed motor; a control device that controls the number of revolutions of the variable speed motor; and an output device that outputs control data to the control device and in which a stretch ratio corresponding to the control data (see FIG. JP 62-110926 A (Page 3, 1 )) is changed. The JP 62-110926 A (Page 3, 1 ) discloses: a method for prestoring pattern data of thickness unevenness to form a thick spot (thickness nonuniformity) as control data; and a method in which a control voltage and a variable-speed motor time are randomly generated by a computer to change the stretch ratio, thereby producing special yarn having an irregularity without substantial periodicity.

Indeed arises in the case of the design of special yarn SY, if it a small amount of thickness thickness adjustment data D, the thick spot length L and the distance P between thick spots gives an undesirable State in which a design that is a repetitive pattern arises, appears on a fabric, that of the special yarn SY was woven. The amount of setting data must be increased, to prevent such a condition. A number of records of approximately 100 is not enough, and about 1000 are needed as Number of records for one Cycle. However, be for it Time and effort needed to enter this data. On the other hand, requires a method of creating random Pattern data with a computer hardly takes time or effort to the Enter data, and can prevent the design in the woven Tissue appears. However, every record is the thick spot S random, and as a result, the same yarn can not be made under full bobbins become. There is therefore a problem that the reproducibility fabric which was woven with the special yarn, not ensured can be.

SUMMARY OF THE INVENTION

The The present invention has been made in view of the above problem and therefore has the object of an apparatus for the production of To provide special yarn with high reproducibility, the is able to produce flame yarn in which there is a design that from repetitive thick spots arises, hardly in a tissue that was woven with it, even with a small amount of input data.

The The present invention relates to a device for the production of special yarn in which a front area forming a stretch area Roller and a rear roller by separate motors with changeable Speed are driven and in the speed the front roller and / or the rear roller is changed according to pattern data, the least information about a distance between Garnunregelmäßigkeiten (thick spots), the Differences in the thickness of woven yarn point to special To produce yarn according to the pattern data. The device comprising: a first storage unit that stores a plurality of pattern records; a second storage unit containing an executable program for executing a stores itself in a cyclical repeating pattern based on the in based on the first memory unit stored pattern records and from pattern records exists that are bigger as those stored in the first storage unit; a third Memory unit that stores information about the pattern records during the execution stores; and a control unit that modifies the motors Speed controls so that yarn, by the execution of the cyclic repeating pattern according to the executable Program is spun.

In This case includes "Save a large number of sample data records "also a case in which: a set of reference pattern data is stored; several Pattern records, where each of them by multiplying a value stored in Reference pattern data is included, at a predetermined amount (rate) is obtained, according to a predetermined rule used to perform a repeating pattern, wherein essentially storing the plurality of pattern records becomes. Further, "a Cyclic repeating pattern "The arrangement of pattern data in which a plurality of different pattern data sets are sequentially sequenced and executable is without containing the same repetitive pattern. "Based on the stored pattern data "is not limited to the stored pattern data itself, but includes using pattern data obtained by multiplying a value which is included in reference data at a predetermined amount (rate), with the stored pattern data as the reference data be generated according to a predetermined rule. Further, "information regarding pattern data while an execution "Information about Determining the pattern data being executed and the pattern data the next accomplished become.

BRIEF DESCRIPTION OF THE DRAWINGS

Accompanying drawings:

1 is a structural view of an apparatus for producing special yarn;

2 is a schematic partial view of a special yarn;

3A and 3B Fig. 11 are schematic diagrams each showing pattern data stored in a pattern table; and

4 Fig. 10 is a schematic diagram showing a pattern table according to Embodiment 3 of the present invention.

DATAILLED DESCRIPTION THE PREFERRED EMBODIMENTS

embodiment 1

The following is with reference to the 1 to 3B Embodiment 1 is described in which the present invention is realized in an apparatus for producing special yarn which forms irregularities by changing the speed of a front roller. 1 is a structural view of an apparatus for producing special yarn, and 2 is a schematic partial view of a special yarn.

The apparatus for producing special yarn has substantially the same structure as a ring fine spinning machine. As in 1 Shown are spindles 1 rotatably driven by a spindle drive system, which is a drive roller 3 by a motor 2 is driven, a driven roller 4 and a tangential belt 5 contains, between the roles 3 and 4 wrapped around this. A variable speed motor powered by an inverter 6 is driven as a motor 2 used, and the engine 2 contains a rotary encoder 2a , A direction axis 7 is rotatably arranged along a spindle column (spindle column). The direction axis 7 is with a lifting and lowering unit 10 (only one unit is shown) at a predetermined interval, which is a ring carrier 8th raises and lowers the one ring 8a along which a traveler T moves, and includes an angle of the thread guide eye (not shown), which is a worm wire 9 contains.

The lifting and lowering unit 10 contains a screw gear 11 , which rotates to the directional axis 7 adapted and fixed, and a threaded body 13 into a screw section 12a screwed in, which is in a lower section of a spar 12 is formed, the ring carrier 8th carries and with the worm gear 11 engaged. The direction axis 7 is with a drive axle of a servomotor 14 by a gear mechanism (not shown), and the servomotor 14 is driven by mutual rotation, thereby raising the ring carrier and lowered. It should be noted that the above structure is substantially the same structure of a device as shown in FIG JP 02-277826A is disclosed. The servomotor 14 contains a rotary encoder 14a and is powered by a servo drive 15 controlled. The direction axis 7 , the lifting and lowering unit 10 , the spar 12 and the like constitute a lifting drive system.

A front roller 17 (showing only a lower roller), which is a stretch area 16 is with a first servomotor 18 connected as a variable speed motor. A middle roller 19 (showing only a lower roller) forming a rear roller is with a second servomotor 20 connected as a variable speed motor. A rear lower roller 21 , which also forms the rear roller, is with the middle roller 19 by means of a gear transmission 22 connected. In other words, the front roller 17 and the other draw rolls, the front roll 17 which heals the rear rollers, are each driven by separate motors of variable speed. Both, the servomotors 18 and 20 each contain rotary encoders 18a and 20a , The middle roller 19 contains a pedestal 19a , A sensor S1 which generates a pulse signal corresponding to the rotation of the front roller 17 is in the environment of the wheel 17a arranged, integral and rotatable on the front roller 17 is attached.

A control device 23a which the respective engines 2 . 14 . 18 and 20 controls, contains a processor (CPU) 24 which forms a control means. The control device 23 contains a program memory 25 as a second storage unit, a working memory 26 as first and third storage unit, an input device 27 , an input interface 28 , an output interface 29 , Motor drive circuits 30 and 31 , a first servomotor drive circuit 32 , and a second servomotor drive circuit 33 , The CPU 24 is with the encoders 2a . 14a . 18a and 20a , the sensor S1 and the input device 27 through the input interface 28 connected. The CPU 24 is with the inverter 6 through the output interface 29 and the motor drive circuit 30 connected and is with the servo drive 15 through the output interface 29 and the motor drive circuit 31 connected. The CPU 24 is with the servomotor 18 through the output interface 29 , the first servomotor drive circuit 32 and a servo drive 34 connected and is connected to the second servomotor 20 through the output interface 29 , the second servomotor drive circuit 33 and a servo drive 35 connected.

The CPU 24 operates based on predetermined program data stored in the program memory 25 are stored. The program memory 25 It consists of a read only memory (ROM) that stores the program data and various types of data needed to run the program.

The program data contains a control program for the engine 2 and the servomotor 14 concerning a winding operation, and a program for controlling the speed of the first servomotor 18 concerning the formation of thick spots by changing the speed of the front roll 17 ,

The program data also includes an executable program for executing a cyclic repeating pattern composed of more pattern data than the pattern data stored in the random access memory 26 based on the pattern data in the working memory 26 are stored.

As in 2 is shown, there is special yarn SY of spun yarn, in the reference portions Y0, each of which has a reference thickness of the spun yarn, and thick portions S, each being thicker than the reference portion Y0, are provided alternately and continuously. A (one) pattern indicates the connection of a reference section Y0 and a thick point S. The special yarn SY is the yarn spun in a state where a plurality of different patterns are sequentially sequenced.

If a thickness of the thick spot S (thick thickness), a length of Thickness S (Thickness Length) and a distance that is an interval between adjacent thick points S is (distance between thick places) corresponding to D, L and P are pattern data from the thickness thicknes D, the thick spot length L and the distance P between thick points of a pattern composed. Thickness thickness D is expressed as a percentage in the case where a Thickness of the reference section Y0 is regarded as 100% expressed. If For example, the thickness thickness D one and a half times as thick as is the thickness of the reference section Y0, D is equal to 150%. If Accordingly, the thickness thickness D is twice as thick as the Reference section Y0, D is equal to 200%. The one-cyclic repeating Pattern indicates an arrangement in which a variety of different Sample records sequentially strung together and executable without the same to contain repeating patterns.

The pattern data is stored in a plurality of pattern tables (two in Embodiment 1). That is, the memory 26 contains two pattern tables 40A and 40B in which a plurality of pattern data sets A1, A2... A (n-1), An and a plurality of pattern data sets B1, B2... B (k-1), Bk are stored correspondingly. It is determined that at least the pitches P between thick points among many pattern data sets A1, A2... A (n-1), An and many pattern data sets B1, B2... B (k-1), Bk are different from each other. The numbers of sample records that are in the pattern tables 40A and 40B stored are different from each other. The respective pattern data sets A1, B1 and the like are stored as a combination of the data values of the thickness thickness D, the thickness point length L and the distance P between thick places (Da1, La1, Pa1), (Db1, Lb1, Pb1) and the like.

The executable program is designed to create a sequence in which the CPU 24 sequentially the pattern data from the different pattern tables 40A and 40B performs. That is, the repetitive pattern for one cycle is set so that one of the pattern data A1, A2, and the like of the pattern table 40A and one of the pattern data B1, B2 and the like of the pattern table 40B alternately lined up (aligned) are. For example, the pattern records become A1 to At the pattern table 40A and the pattern data sets B1 to Bk of the pattern table 40B executed sequentially and alternately. After the last pattern data of the corresponding pattern table is executed with respect to the pattern table, the execution of the first pattern data is repeated in the sequential order.

The different types of data stored in the program memory 25 are stored spinning conditions such as fiber material, counter of the spun yarn having a reference thickness and a stretch ratio, and data corresponding to the spindle rotation speed at a time of steady state operation, rotation speeds of the first servo motor 18 and the second servomotor 20 , and a lifting and lowering speed of the ring carrier 8th , Further, the various types of data include an acceleration gradient and a deceleration gradient at a time of controlling the speed of the first servomotor 18 in forming thick spots, and a calculation equation of the rotational speed of the front roll 17 for obtaining the thick patch thickness D (%) according to the pattern data of the specific yarn.

The working memory 26 consists of a random access memory (RAM) and temporarily stores data through the input device 27 be entered, processing results of the CPU 24 and the same. The working memory 26 includes an uninterruptible power supply (not shown).

The input device 27 is for inputting data on spinning conditions, such as pattern data of special yarn, counter of spun yarn having a reference thickness, a spindle rotation speed at a time of spinning the spun yarn using a reference thickness, a lever length and a track length.

Next, the operation of the apparatus provided as above will be described. Before operating the machine, first the spinning conditions have to be done via the input device 27 be entered. The data regarding the pattern data of the specific yarn, counter of spun yarn having a reference thickness, a spindle speed at a time of spinning the spun yarn having a reference thickness, a lever length, a track length, and the like are input as the spinning conditions. In the case where some of the spinning conditions, the same as those at the time of the last operation and already stored and in the working memory 26 only the other operating conditions different from those at the time of the last operation must be entered.

Then with a start-up of the engine, the engine 2 , the servomotor 14 , the first servomotor 18 and the second servomotor 20 driven and according to a command from the control device 23 controlled. The CPU 24 calculates the rotational speeds of the respective motors according to the output signal from the corresponding encoders 2a . 14a . 18a and 20a , After that, the CPU gives 24 the command signals for operating the spindle drive system, a stretch range drive system and the lift drive system in synchronization with the predetermined speed corresponding to the spinning conditions, to the inverter 6 and the servo drives 15 . 34 and 35 through the output interface 29 and the respective drive circuits 30 to 33 out. The spindle drive system, the stretch range drive system and the lift drive system are operated independently synchronously. The special yarn SY, that of the draw area 16 is delivered to a coil B via the worm wire 9 and the runner T wound.

The CPU 24 reads the pattern data to be executed from the pattern table 40A and the pattern table 40B alternately, based on the sequence controlled by the executable program, and stores the data in the working memory 26 , And the CPU 24 Controls the number of revolutions of the front roller 17 such that the thickness D, thickness L and the distance P between thick places included in the pattern data to be executed are obtained. The CPU 24 calculates the length of the spun yarn according to the thick spot length L and the pitch P between thick places based on the number of revolutions of the front roll 17 corresponding to the output signal of the sensor S1, thereby indicating an acceleration starting point and a deceleration starting point of the front roller 17 certainly.

The CPU 24 controls the first servomotor 18 such that the front roller 17 at a reference speed N0 corresponding to the thickness of the reference portion Y0 rotates while spinning the reference portion Y0. Furthermore, the CPU calculates 24 when spinning the thick spot S, the rotational speed of the front roller 17 corresponding to the thick thickness D% and reduces the rotational speed to the calculated. After the reduction has begun, the CPU controls 24 the first servomotor 18 such that the speed is increased again to the reference speed N0 when the thick point is spun for its length L. Thus, the spinning of a pattern data unit is completed. After that, the speed of the front roller 17 so controlled the rotation speed is obtained according to the following pattern data.

The corresponding sequences for reading the pattern data sets A1, A2... A (n-1), An and the pattern data sets B1, B2... B (k-1), Bk from the corresponding pattern tables 40A and 40B are A1 to An with respect to the pattern table 40A and B1 to Bk with respect to the pattern table 40B , Regarding the pattern table 40A After the last pattern data unit An has been executed, the first pattern data set A1 is again sequentially executed. The number of pattern data sets (pattern data number) of the cyclic repeating patterns obtained according to the above sequence is twice the least common multiple of the pattern data set numbers of the respective pattern tables 40A and 40B ,

For example, if n = 3 and k = 2, the executable sequence is the same as the CPU 24 the sequence of A1, B1, A2, B2, A3, B1, A1, B2, A2, B1, A3, B2, A1, B1 .... In this case, the repetitive pattern is executed with a data number of 12, ie, A1, B1 through A3, B3. The number of input pattern records is n + k = 3 + 2 = 5; however, the same effect as that by inputting 12 records, which is twice as large as the least common multiple of the pattern record number n (= 3) of the pattern table, can be the same 40A and the pattern data set number k (= 2) of the pattern table 40B (3 × 2 = 6).

Further, if n = 4 and k = 2, the executable sequence corresponds to the CPU 24 the sequence of A1, B1, A2, B2, A3, B1, A4, B2, A1, B1 .... In this case, the pattern data set number is n + k = 4 + 2 = 6; however, the same effect as that obtained by inputting eight data sets, which is twice as large as the least common multiple of the pattern data set number n (= 4) and the pattern data set number k (= 2) (2 × 2 = 4).

That is, in the case where the pattern data set number relative to one of the pattern tables 40A and 40B is input, one divisor of the pattern data set number entered with respect to the other is, the least common multiple of the two numbers is equal to the larger pattern data set number. Thus, the least common multiple is not larger compared to the sum of the pattern data set numbers (n + k). Therefore, the pattern data numbers corresponding to the corresponding pattern tables become 10A and 40B are preferably set so that the pattern data set number of one of the pattern tables is not a divisor of the pattern data set number of the other pattern table. Preferably, the pattern data set numbers of the respective pattern tables are prime numbers.

With respect to the pattern data set number realizing a state in which a design resulting from a repeating pattern does not appear in a fabric woven with the special yarn SY, about 100 is insufficient, and becomes about 1,000 for one cycle needed. If it is assumed that an appropriate input pattern data set number 50 , as the sum of the pattern data set numbers of the pattern tables 40A and 40B , and that the respective pattern data set numbers are prime numbers, for example, 33 and 17, the pattern data set number of the one-cycle repeated pattern is 33 × 17 × 2 = 1,122. That is, the pattern data set number of the cyclic repeating pattern can be greatly increased as compared with the input data set number.

• (1) Basierend auf den Musterdaten, die in dem Arbeitsspeicher 26 gespeichert sind, ist das ausführbare Programm zum Ausführen des sich einzyklisch wiederholenden Musters, das aus den Musterdatensätzen, die größer als die in dem Arbeitsspeicher 26 gespeicherten Musterdatensätzen, sind, besteht, in dem Programmspeicher 25 gespeichert. Dann enthält die Fertigungsvorrichtung die CPU 24 (Steuerungseinheit), die den ersten Servomotor 18 so steuert, dass Garn gesponnen wird, das durch Ausführen des sich einzyklisch wiederholenden Musters entsprechend des ausführbaren Programms erhalten wird. Daher wird es möglich, das spezielle Garn SY (Flammengarn) mit einer hohen Reproduzierbarkeit herzustellen, wobei ein Design, das aus Wiederholungen der Unregelmäßigkeiten entsteht, im Gewebe, das damit gewoben wird, kaum erscheint, selbst mit einer geringen Menge von Eingabedaten (Musterdaten).
• (2) Die Musterdaten werden in einer Vielzahl von Mustertabellen 40A und 40B gespeichert, und das sich einzyklisch wiederholende Muster ist so festgelegt, dass die Musterdaten der unterschiedlichen Musterdatentabellen abwechselnd aneinandergereiht (aligned) sind. Daher wird es unter der Bedingung, dass dieselbe Musterdatensatzanzahl verwendet wird, einfacher, ein sich einzyklisch wiederholendes Muster festzulegen, in dem dieselben Musterdaten nicht fortlaufend aneinandergereiht sind, sondern das eine große Anzahl von Musterdaten aufweist verglichen mit dem Fall einer einzigen Mustertabelle.
• (3) Die Anzahlen der Musterdatensätze, die in den jeweiligen Mustertabellen 40A und 40B gespeichert sind, unterscheiden sich voneinander. Das ausführbare Programm, das die Sequenz der Ausführung der Musterdaten bestimmt, ist so strukturiert, dass es die Sequenz ist, durch welche die Musterdatensätze von den unterschiedlichen Mustertabellen 40A und 40B abwechselnd und sequenziell ausgeführt werden. Daher kann die Sequenz der Ausführung der Musterdatensätze einfach bestimmt werden.
• (4) In dem Fall, in dem die Anzahl der Musterdatensätze, die in den Mustertabellen 40A und 40B gespeichert sind, Primzahlen sind, wird die Anzahl der Musterdatensätze, die das sich einzyklisch wiederholende Muster bilden, größer als die der anderen, selbst wenn die gleiche Gesamtanzahl von Musterdatensätzen angewendet wird.
• (5) Jeder der Musterdatensätze enthält nicht nur die Informationen bezüglich des Abstands P zwischen Dickstellen, sondern auch die Information bezüglich der Dickstellendicke D und der Dickstellenlänge L. Daher ist es möglich, spezielles Garn mit einem komplizierteren Muster herzustellen.
• (6) In dem Fall des Festlegens einer Anordnung der sich einzyklisch wiederholenden Musterdaten mit der Verwendung der Vielzahl von Musterdatensätzen, die in den jeweiligen Mustertabellen 40A und 40B gespeichert sind, ist nicht die gesamte Anordnung der sich einzyklisch wiederholenden Musterdaten in dem Arbeitsspeicher 26 gespeichert. Daher kann die Größe des Arbeitsspeichers 26 reduziert werden, verglichen mit dem Fall des Speicherns der gesamten Anordnung der sich einzyklisch wiederholenden Musterdaten in dem Arbeitsspeicher 26.
• (7) Die Dicke des gesponnenen Garns wird durch Veränderung der Geschwindigkeit der vorderen Walze 17 verändert. In dem Verfahren zur Ausbildung der Dickstellen S durch Veränderung des Streckverhältnisses durch Änderung der Geschwindigkeit der mittleren Walze 19, selbst wenn sich das Streckverhältnis durch die Beschleunigung der mittleren Walze 19 verringert, ist der Zustand des Erscheinungsbilds der Dickstelle S schwer aufgrund des Einflusses von Vlies zu reproduzieren, das zwischen der Spitze des Sockels 19a der mittleren Walze 19 und dem Spalt (nip point) der vorderen Walze 17 besteht. Daher wird in dem Fall einer kurzen Dickstelle (mit einer Länge von einigen zehn Millimetern) die Dickstelle S nicht deutlich. Allerdings wird in der Ausführungsform 1 die Änderung der Dicke des gesponnenen Garns durch Änderung der Geschwindigkeit der vorderen Walze 17 durchgeführt. Dementsprechend ist die Dickstelle S deutlich, selbst wenn die Dickstellenlänge einen kleinen Wert aufweist.

The embodiment 1 provides the following effects.

• (1) Based on the pattern data stored in the working memory 26 is the executable program for executing the cyclic repeating pattern that is the pattern data sets larger than those in the working memory 26 stored pattern records are, in the program memory 25 saved. Then, the manufacturing device includes the CPU 24 (Control unit), which is the first servomotor 18 so that yarn is spun, which is obtained by executing the cyclic repeating pattern according to the executable program. Therefore, it becomes possible to produce the special yarn SY (flame yarn) with a high reproducibility, and a design resulting from repetition of the irregularities hardly appears in the woven fabric woven therewith even with a small amount of input data (pattern data). ,
• (2) The pattern data is in a variety of pattern tables 40A and 40B is stored, and the cyclic repeating pattern is set so that the pattern data of the different pattern data tables are alternately aligned. Therefore, under the condition that the same pattern data set number is used, it becomes easier to set a one-cyclic repeating pattern in which the same pattern data is not consecutively strung, but has a large number of pattern data as compared with the case of a single pattern table.
• (3) The numbers of the sample data records that are included in the respective sample tables 40A and 40B stored are different from each other. The executable program that determines the sequence of execution of the pattern data is structured to be the sequence through which the pattern records differ from the different ones pattern tables 40A and 40B alternately and sequentially. Therefore, the sequence of execution of the pattern records can be easily determined.
• (4) In the case where the number of pattern records contained in the pattern tables 40A and 40B are stored, are prime numbers, the number of pattern records constituting the one-cyclic repeating pattern becomes larger than those of the others even if the same total number of pattern records are applied.
• (5) Each of the pattern data sets contains not only the information regarding the pitch P between thick spots, but also the information regarding the thickness D and the thickness L of length. Therefore, it is possible to produce special yarn having a more complicated pattern.
• (6) In the case of specifying an arrangement of the cyclic repeating pattern data with the use of the plurality of pattern data sets shown in the respective pattern tables 40A and 40B is not the entire arrangement of the cyclic repeating pattern data in the working memory 26 saved. Therefore, the size of the memory 26 compared with the case of storing the whole arrangement of the cyclic repetitive pattern data in the work memory 26 ,
• (7) The thickness of the spun yarn is changed by changing the speed of the front roll 17 changed. In the method of forming the thick spots S by changing the draw ratio by changing the speed of the middle roll 19 Even if the draw ratio is due to the acceleration of the middle roll 19 reduced, the state of appearance of the thick spot S is difficult to reproduce due to the influence of fleece, which is between the top of the base 19a the middle roller 19 and the nip point of the front roller 17 consists. Therefore, in the case of a short thick patch (with a length of several tens of millimeters), the thick spot S does not become clear. However, in Embodiment 1, the change in the thickness of the spun yarn is changed by changing the speed of the front roll 17 carried out. Accordingly, the thick spot S is clear even if the thick spot length has a small value.

embodiment 2

Hereinafter, Embodiment 2 will be described. Embodiment 2 differs from Embodiment 1 in that the CPU 24 the order of the respective reading of the pattern data sets A1, A2,... A (n-1), An and the pattern data sets B1, B2,... B (k-1), Bk from the pattern tables 40A and 40B is determined based on a rule different from that in Embodiment 1 and that the pattern data set number of the pattern table 40A equal to the pattern table 40B can be. The other constituents of the structure of the manufacturing apparatus in Embodiment 2 are the same as those in Embodiment 1. The same structural components as those in Embodiment 1 are denoted by the same reference numerals, and the descriptions thereof are omitted or simplified here.

In Embodiment 2, in the case where the pattern data set number of the pattern table 40A yourself from the pattern table 40B is different, the pattern data sets A1, A2, ... A (n-1), An and the pattern data sets B1, B2, ... B (k-1), Bk become sequential and alternate from the respective pattern tables 40A and 40B read based on the same rule as in Embodiment 1.

On the other hand, in the case where the pattern data set number of the pattern table 40A equal to the pattern table 40B is, that is, when k = n, are for the pattern table 40A the pattern data sets are executed sequentially in the sequence from A1 to An from the first cycle to the nth cycle. However, for the pattern table 40B the pattern data sets are executed sequentially in the sequence from B1 to Bk during the first cycle. During the next cycle, execution starts with the second pattern record B2 and ends with the pattern record B1. That is, for the pattern table 40B the execution starts with the ith pattern data set during the ith cycle, and ends with the (i-1) th pattern data set.

For example, if n and k are both 3, the executable sequence is the same as the CPU 24 the sequence of A1, B, A2, B2, A3, B3, A1, B2, A2, B3, A3, B1, A1, B3, A2, B1, A3, B2, A1, B1 .... In this case, the pattern data set number is n + k = 3 + 3 = 6. However, the same effect as that of inputting 18 records, which is twice as large as the product of the pattern record number n (= 3) of the pattern table, can be obtained 40A and the pattern data set number k (= 3) of the pattern table 40B (3 × 3 = 9).

For example, if n and k are both 4, the executable sequence corresponds to the CPU 24 the sequence of A1, B1, A2, B2, A3, B3, A4, B4, A1, B2, A2, B3, A3, B4, A4, B1, A1, B3, A2, B4, A3, B1, A4, B2 , A1, B4, A2, B1, A3, B2, A4, B3, A1, B1 .... In this case, the pattern data set number is n + k = 4 + 4 = 8. However, the same effect can be achieved as entering 32 records, which is twice as large as the product of the pattern record number n (= 4) of the pattern table 40A and the pattern data set number k (= 4) of the pattern table 40B (4 × 4 = 16).

That is, when the pattern data set numbers of the pattern tables 40A and 40B each n and k, the pattern data set number of the one-cycle repeating pattern corresponds to the product of: the combination of selecting a data unit from the pattern data in the pattern table 40A , combining the selection of data from the pattern data in the pattern table 40B ; and the number of pattern tables, ie _n C ₁ × _k C ¹ × 2.

• (8) Unabhängig davon, ob die Musterdatensatzanzahlen n und k in den jeweiligen Mustertabellen 40A und 40B gleich sind oder nicht, und n oder k ein Teiler des anderen ist oder nicht, entspricht die Musterdatensatzanzahl des sich einzyklisch wiederholenden Musters dem Produkt der Kombination der Auswahl von Daten von den Musterdaten in den jeweiligen Mustertabellen 40A und 40B, und der Anzahl der Mustertabellen, d.h. _nC₁ × _kC¹ × 2. Dementsprechend wird der Freiheitsgrad des Festlegens der Anzahl der Datensätze, die jeweils den Mustertabellen 40A und 40B eingegeben werden, erhöht, verglichen mit dem Fall in Ausführungsform 1.

Accordingly, the embodiment 2 besides the effects (1), (2) and (5) to (7) of the embodiment 1 provides the following effects.

• (8) Regardless of whether the pattern data numbers n and k in the respective pattern tables 40A and 40B are the same or not, and n or k is a divisor of the other or not, the pattern data set number of the one-cycle repeating pattern corresponds to the product of the combination of selecting data from the pattern data in the respective pattern tables 40A and 40B , and the number of pattern tables, ie, _n C ₁ × _k C ¹ × 2. Accordingly, the degree of freedom of setting the number of records corresponding to the pattern tables 40A and 40B are inputted, compared with the case in Embodiment 1.

embodiment 3

When next becomes the embodiment 3 described. embodiment 3 differs from Embodiments 1 and 2 in that that a single pattern table is provided and in that the number of records, which is stored in the pattern table is one. The others Components of the structure of the manufacturing apparatus in embodiment 3 are the same as those in embodiment 1. The same structural areas as those in embodiment 1 are denoted by the same reference characters and the description this is simplified or omitted.

In Embodiment 3, as in FIG 4 is shown, the reference pattern data C0 in a pattern table 40C is stored as a combination of thick-thickness D data, thick-point length L and pitch P between thick points (Dc0, Lc0, Pc0). Then the executable program is such that the CPU 24 A plurality of different pattern data sets Ci are formed based on a predetermined rule from the data values of the reference pattern data set C0, and a plurality of pattern data sets Ci (Dci, Lci, Pci) are executed in a predetermined sequence.

For example, the CPU multiplies 24 successively the data values of the reference pattern data C0 having a coefficient which has been increased by a predetermined amount (for example, 5%), thereby forming the pattern data sets Ci (Dci, Lci, Pci). It should be noted that i denotes the ith number in a predetermined sequence. As the sequence, an arithmetic series or geometric series is used. Dci = Dc0 × 1.05 × i, Lci = Lc0 × 1.05 × i and Pci = Pc0 × 1.05 × i. Then the CPU performs 24 a plurality of pattern data sets Ci (Dci, Lci, Pci) in a predetermined sequence.

That is, in Embodiment 3, the reference data set C0 is in the pattern table 40C stored, the pattern data, which are determined by multiplying the thickness Thickness D, thick point length L, and distance P between thick places contained in the stored reference pattern data set C0, with the predetermined amount, based on a predetermined rule.

• (9) Da die Anzahl der Mustertabelle 40C, die die Musterdaten speichert, eins ist, kann ein Speicherbereich des Arbeitsspeichers 26, der zur Speicherung der Mustertabelle 40C benötigt wird, verkleinert werden.
• (10) Da lediglich der Referenzdatensatz C0 (gespeichert) in die Mustertabelle 40C eingegeben wird, benötigt die Eingabe der Musterdaten weniger Zeit und Aufwand.

Accordingly, Embodiment 3 provides the following effects besides the effects (1) and (5) to (7) of Embodiment 1.

• (9) Because the number of pattern table 40C , which stores the pattern data, may be a memory area of the working memory 26 , to store the pattern table 40C is needed, be scaled down.
• (10) Since only the reference data set C0 (stored) in the pattern table 40C is entered, the input of the pattern data takes less time and effort.

The The present invention is not limited to the above-described embodiments limited. For example, you can the following realizations are performed.

It it is sufficient that the pattern data at least the information in terms of of the distance P between thick places. For example, can at least one of the thickness thickness D and the thickness point length L, which the patterns of the special yarn SY form, are kept constant. In such a case must the constant conditions are not set for the pattern data and the formation of the pattern data becomes easy.

Instead of the structure in which the pattern data is in memory 26 may be inputted, a structure may be applied in which the pattern data in the rewritable ROM (EPROM, EEPROM) or in the pattern data in the program memory 25 be pre-stored. In these cases, the rewritable ROM or the program memory constitute 25 the first storage device tung.

In the embodiments 1 and 2, the sequence of reading the pattern records in each of the Sample tables do not start with A1 or B1. Any starting point can be chosen as long as a predetermined sequence is used.

In in the case of specifying an arrangement of the cyclically repeating ones Pattern data using a plurality of pattern data sets that are stored in a plurality of pattern tables as in embodiment 1, the arrangement is not limited to one in FIG the the pattern records the different pattern tables lined up alternately but an arrangement can be applied which allows the pattern records from the same pattern table consecutively in a part of the arrangement string together. In this case, even if the pattern data set number, which is input to the pattern table, equal to the one applied is the number of repeating pattern records in one Cycle increased become.

The present invention is not limited to a structure in which all the pattern data stored in the pattern tables are used for executing the one-cycle repeating pattern as shown in Embodiments 1 and 2, but a structure may also be adopted. in the pattern records larger than the pattern records used in the execution of the one-cycle repeating pattern are prestored in the pattern tables, and the pattern records selected from the stored pattern records are used to execute the one-cycle repeating pattern. In this case, if the pattern records are stored in the program memory 25 Storing pattern data takes little time and effort. Further, the inputting of the pattern data does not have to be always performed again when different yarn SY is produced. Accordingly, special yarn SY can be more easily manufactured.

Instead of the structure in which a variety of pattern records in a variety of pattern tables can be stored, a structure be applied, in which a variety of pattern records in a pattern table is stored.

In the case of setting the arrangement of the one-cycle repeating pattern data with the use of a plurality of pattern data sets, the entire arrangement of the one-cycle repeating pattern data in the work memory 26 get saved. In this case, even if the arrangement sequence of the pattern data sets is determined using, for example, a table of random numbers, the same specific yarn SY can be produced with a high reproducibility by storing the designated pattern data arrangement in the working memory 26 getting produced.

When the pattern data through the input device 27 may be inputted, instead of the structure in which a sequential input of the thickness thickness D (%), the thickness position length L and the pitch P between thick places is performed, a structure may be adopted in which the input device 27 one of many types of pattern data selected in the program memory 25 are pre-stored.

When the thickness of the yarn to be spun is changed, the structure of changing the speed of the middle roll can be changed 19 (rear roller) are used instead of that of changing the speed of the front roller 17 , In a ring spinning machine, the time of a full bobbin becomes an integral value of the rotational speeds of the front roller 17 estimated, and a preparation for slimming is performed according to the time of a filled coil. A cleaning device that moves along the machine is also automatically returned to the position so as not to disturb the removal operation. In the method of forming thick spots S by changing the draw ratio by changing the speed of the front roll 17 , it is difficult to estimate a time for a filled bobbin to interfere with the preparation to remove or automatically return the cleaning device to a recirculating position. However, in the case of changing the thickness of the spun yarn by changing the speed of the middle roll 19 the estimation of the time of a filled coil is performed as in a conventional ring spinning machine.

In the case of producing the special yarn (flame yarn) SY mainly containing thick spots S, each of them having a thickness obtained by changing the speed of either the front roll 17 or the middle roller 19 (rear roller) can not be achieved, the speeds of both, the front roller 17 and the middle roller 19 , to be changed to spin the thick places S. In the case of significantly changing the thickness of the thick spot S with respect to the thickness of the reference section Y0, the draw ratio corresponding to the desired thickness could not be changed merely by changing the rotational speed of the front roller 17 or the middle roller 19 to be obtained. By contrast, when spinning the thick places S, the front roller 17 ver hesitates while the middle roller 19 (rear roller) is accelerated relative to the speed at a time of spinning the reference portion Y0. Thus, the stretch area corresponding to the desired thickness can be obtained.

In the case where the thickness D (%) shown by the pattern data has a value not smaller than a predetermined value (for example, 200%), if the thickness D (%) has a value which is smaller than the predetermined value, a structure can be applied in the spinning by changing the speed of either the front roller 17 or the middle roller 19 is carried out. In this case, regardless of the thickness D (%), the control can be compared with the case where the speed of both the front roller 17 and the middle roller 19 , being changed, being easy.

In the case of the structure in which a change in the speed of the front roller 17 is not performed at a time of spinning the thick spot S, a structure can be applied in which the spindles 1 and the front roller 17 be driven by the same motor.

Instead of the structure in which the middle roll 19 with the rear lower roller 21 through the gear transmission 22 connected, a structure can be applied in which the middle roller 19 and the rear lower roller 21 be driven by different motors of variable speed.

The present invention can be applied to a device one draw roll having four or more lines, contains.

Claims (6)

A special yarn manufacturing apparatus in which a stretch forming front roller and a rear roller are driven by separate variable speed motors, and wherein the speed of the front roller and / or the rear roller is changed in accordance with pattern data containing at least information about include a pitch between yarn irregularities showing differences in the thickness of spun yarn to make specific yarn according to the pattern data, characterized in that the apparatus comprises: a first storage unit storing a plurality of pattern data sets; a second storage unit that stores an executable program for executing a one-cycle repeating pattern based on the pattern records stored in the first storage unit and consisting of pattern records larger than those stored in the first storage unit; a third storage unit that stores information about the pattern records during execution; and a control unit that controls the variable speed motors so as to spun yarn obtained by executing the cyclic repetitive pattern according to the executable program. Apparatus for producing special yarn according to Claim 1, characterized in that: the pattern records in one Variety of pattern tables are stored; and the executable program is set up so that the pattern records of the various pattern tables are arranged alternately. Apparatus for producing special yarn according to Claim 2, characterized in that the number of pattern records, the stored in each of the pattern tables is a prime number. Apparatus for producing special yarn according to Claim 2, characterized in that: two pattern tables to be provided; the numbers of the sample data records, the stored in the corresponding pattern tables, from each other differ; and the pattern records one by one in a predetermined sequence from the corresponding pattern tables and after the last pattern record in the reading order was executed, execution starts again from the first pattern data set. An apparatus for producing special yarn according to claim 2, characterized in that: two pattern tables are provided; in the case where the numbers of the pattern data sets stored in the respective pattern tables are different from each other, the pattern data sets are read one after another in a predetermined order from the corresponding pattern tables, and after the last pattern data set in the reading sequence has been executed that execution starts again from the first pattern data set; and in the case where the number of each pattern data set stored in the respective pattern tables is n, the pattern data sets in one of the pattern tables are in a predetermined order from a first cycle to an nth cycle and in the other pattern table of a second cycle, the execution starts sequentially from a second pattern record in the previous cycle and ends with the execution of the first pattern record of a previous cycle. Device for producing special yarn according to one of the claims 1 to 5, characterized in that each of the pattern records also the Information regarding Strength and length the yarn irregularities contains.