CH686156A5 - Bobbin identification - Google Patents

Abstract

To identify material in the textile industry, such as bobbins to show the content and quality and prodn. data, a data carrier is applied directly to the bobbin and the like which is machine readable and machine written. The data carrier is amended at each prodn. stage and can be transferred from stage to stage, as the data are available for access at any time during prodn. and during any further processing. The data carrier is directly at the bobbin or other material unit, using an integrated circuit with an antenna. Pref. the data carrier is an integrated circuit with a memory for machine written data. The data writing and scanning is through electromagnetic rays, without physical contact, operating in the HF and pref. microwave ranges. The data are protected against unauthorised access. The data carrier is fitted at or in the sleeves of the bobbins. When the bobbin is unwound, the date are transferred from the old bobbin to the rewound bobbin. The carrier has a microprocessor for its own intelligence. A writing/scanning system (7 ,7', 9, 13) gives the data exchange, with the communications protocol and data access controlled through the microprocessor.

Description

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description

The present invention relates to a method for material identification and for material-related data transport in the textile industry, in which a machine-writable and readable data carrier is assigned to each material unit.

Such methods play an increasingly important role today in the context of quality control of the work results of spinning machines and in the context of production and quality monitoring in the spinning mill, as they make it possible to determine from which production site (e.g. flyer, card, route delivery, spinning or winding station) a material unit originates, and on the other hand make decisions about the further processing of the material unit based on its individual production and quality data.

After starting years ago to provide the individual spinning heads with a marking identifying the individual spinning position (CH-A 410 717 and 410 718), which was deleted after winding, proposals have recently been known for spools on transport plates to put on and to provide the latter with identification marks. Proposals of this type can be found, for example, in DE-A 3 628 045 and in DE-A 4 112 073.

These known solutions are certainly practicable when it comes to being able to trace the production or quality data of individual products back to the individual immediately preceding spinning or winding positions in a machine system consisting of a ring spinning machine and a winding machine. However, they are unsatisfactory if tracing should also be possible due to an event occurring in a later process stage.

For example, DE-A 4 112 073 describes a system for monitoring production in a spinning mill, in which the spinning bobbin is placed on a first transport plate and fed to an automatic winder, the bobbin taken off by the latter is loaded onto a hanging transport basket and transported therein, and finally the package removed from the hanging transport basket, placed on a second transport plate and fed to a test station.

If a problem occurs with regard to quality or production in the spinning mill or at a subordinate stage after the products have been dispatched, such as weaving or dyeing, the origin and processing route of the product should be made detectable on the basis of recorded data. For this purpose, storage and recording media for the data to be stored are provided on the first and second transport plates and on the hanging transport basket, these data being exclusively machine and production point numbers. Finally, the previously saved data is added to the coil ready for delivery as a label. Any quality data is not recorded on the storage media, but recorded and collected in a central control device, wherever,

This is done indirectly, the quality data is assigned to the numbers contained on the storage media.

With this method, the number of the production site of the spools can still be determined after shipping to the customer, but it is questionable how the associated quality data should be determined. It is also clear that the system can be severely disrupted by manual intervention, for example by removing individual coils for testing purposes, or by other external influences, such as voltage interruptions.

The invention is now intended to provide a much simpler and more reliable method for assigning data to a material unit, which can also be installed retrospectively, in the form of a so-called retrofit solution, and also during manual interventions, such as removing the material units, and, in the event of external disturbances, enables a clear and reliable assignment between the material unit and the data carrier.

According to the invention, this object is achieved in that the data carrier is arranged directly on the respective material unit and subjected to production and quality data, and in that between the various stages of the production process the data mentioned is transferred from one stage to the other so that the Data are available during the entire production process and preferably also during the further processing of the material unit.

In the method according to the invention, therefore, no additional carriers are required for the data carriers, but these are arranged directly on the respective material units. Material unit means an individual body of a textile material in the yarn manufacturing or finishing process, which body can consist of bare textile material (bales of fiber), of textile material wound on a carrier (sleeve) or of textile material arranged in a container (jug). If the carrier of the material unit changes (for example when changing from cop to cheese), there is a data transfer between the different carrier types.

The finished package goes to the customer with the data carrier and carries its resume, so to speak, so that it can be traced back to the spinning position at the time. A particular advantage of the data carrier arranged on the material unit is that a subsequent retrofitting of a spinning / winding facility from conventional spools to those according to the invention is easily possible and does not require complex interventions in the existing machines.

It is even possible, provided that standard sleeves are used for the packages (type of data carrier and their arrangement on the package are specified), that the processor of the package also writes the data carrier with quality data and the empty packages on the Yarn manufacturer returns. The yarn5

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From a comparison of the quality data of the yarn production and the yarn processing, herteiler can then make reliable statements about the yarn properties and will be able to supply the exactly right and suitable yarn for a requirement profile desired by the customer.

The invention further relates to a data carrier for material identification and for the accompanying data transport in the textile industry, with a machine-readable and writable data memory.

The data carrier according to the invention is characterized in that it is arranged directly on the respective material unit and is formed by an integrated circuit with an antenna.

The invention is explained in more detail below with reference to the drawings; it shows:

1 is a view of a spinning cop and a package,

FIG. 2 shows an enlarged detail from the sleeve of the spinning cop or the package of FIG. 1; and

Fig. 3 is a schematic representation of a bobbin transport system for a spinning / winding machine.

Fig. 1 shows a spinning cop SK on the left and a cheese KS on the right, which consist of a sleeve 1, that is the yarn carrier, and the yarn 2 wound on the sleeve 1. As shown, the yarn 2 does not cover the entire length of the sleeve 1, but is surmounted by it for a short distance at both ends.

A data carrier 3 is attached to each sleeve 1 in order to enable automatic assignment of data to the individual spinning heads SK and cross-wound bobbins KS and automatic identification thereof. The data carrier 3 can be machine-written with data and the data can be machine-read from it; it consists of an antenna and a chip with an area of a few square millimeters. It can be written with data by a radio frequency transmitter; its data can be read in the same way. The data is preferably secured so that only the respective authorized have access to the data and the access options can be designed selectively. In order to achieve the necessary data security, the chip of the data carrier 3 preferably contains a microprocessor which controls the communication protocol and restricts data access.

There are practically no restrictions on the type and dimensions of the data carrier 3 for the location of the mounting of the data carrier 3 on the sleeve 1. This can be embedded in the sleeve, either in the area of the yarn-free ends or in the spooled area, or it can be applied to the outer or the inner wall of the sleeve 1. Two of these different attachment options for the data carrier 3 on or in the sleeve 1 are indicated in FIG. 2.

The location of the attachment of the data carrier 3 on the sleeve 1 is essentially determined by the antenna used. If the antenna is located directly on the chip, then this must be at a relatively close distance of, for example, no more than 1 cm from the transmitter during data communication. If, on the other hand, the antenna is attached to the chip, there is extensive freedom with regard to the location of the chip.

Of the various mounting options for the data carrier 3, embedding in the sleeve wall is the most recommended because damage from the outside is largely excluded here. The arrangement on the spooled outer part of the sleeve 1 is advantageous because here the data carrier 3 is protected by the yarn.

The data carrier 3 contains a memory with sufficient capacity of, for example, 1 kilobyte, into which the various data can be written via the respective coil. On the one hand, these data are pure production data (number of the spinning machine and spinning station, date, shift number) and, on the other hand, quality data, for example thread cleaner data, which are determined during winding.

The system shown in FIG. 3 is essentially a machine system consisting of a ring spinning machine RS and a winding machine SM, with an upstream sleeve bearing 4 and a downstream coil bearing 5. The ring spinning machine RS comprises a number of spinning positions Si to Sn, those from the sleeve bearing 4 supplied with data carriers 3 sleeves 1 of the type shown in FIGS. 1 and 2 and on which spinning bobbins SK are produced from the roving of flyer spools. The latter are transported in the direction of arrow A to the winding machine SM after being pulled off by a first conveyor mechanism 6.

Each spinning station Si to Sn is equipped with a read / write device 7, which is provided for data communication with the sleeves of the flyer spools and the spinning heads. The spindle number and any quality data of the previous processing stages contained on the flyer spool are transferred to the data carrier 3 of the spinning head sleeves. This quality data can include, for example, fiber parameters (micronaire, pile length, dirt content, degree of maturity, etc.) and tape parameters (tape number, CV%) of the card and draw frame. If the RS ring spinning machine is connected to a process control system such as USTER RINGDATA (USTER and RINGDATA are registered trademarks of Zellweger Uster AG), then of course the quality data (thread breaks, information about yarn twist and the like) determined by this system for the individual spinning positions will also be displayed ) written in the data carrier 3. This data can also be written in by a read / write station 7 'arranged between the ring spinning and winding machine.

Following the latter, the spinning cops SK arrive at a thread end search device 8 of one of the winding positions Wi to Wm of the automatic winder SM and the thread is unwound and thereby

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tronically cleaned. A read / write station 9 is provided at each winding unit Wi to Wm, which reads the production data of the data carrier of each spinning head SK and enters it into the data carrier of the respective cross-wound package KS together with the data obtained during the winding process. The function of the yarn cleaner is assumed to be known and is not explained in more detail here; in this connection, reference is made, for example, to the USTER POLYMATIC cleaning system (USTER - registered trademark of Zellweger Uster AG).

USTER POLYMATIC has four error channels, a so-called S channel for the short and an L channel for the long thick sections, a T channel for thin sections and a C channel for the thread number. The data from these channels, to which further quality data can be added, are written by the read / write station 9 into the data carrier of the cheese KS. It now contains all the essential production and quality data for the yarn wound on the package.

The data stored on the data carrier are used essentially for two purposes, on the one hand as a type of certificate for the spooled yarn and on the other hand for the detection of faulty spinning positions. The function as a certificate is to be understood in such a way that the cross-wound bobbin KS, which is transported into the bobbin store 5 via a second conveyor mechanism 10 and is delivered to the customers from there, comes to the customer together with its data carrier. If the latter has a suitable reading device, it can query important data from the data carrier at any time.

As a rule, the yarn manufacturer will not want the customer to have free access to all the data stored on the data carrier and will therefore secure the data that is not freely accessible accordingly. This security can look such that this data is only accessible to users who have a secret additional key or additional code in addition to the reading device. If the customer has any complaints, he can send the spool back to the manufacturer and the manufacturer can use the data stored on the data carrier to trace the history of the spool completely.

If thread cleaner data are present that are outside the specified limit values, intervention can be made at the corresponding spinning position and the cop in question can be ejected. This intervention can be triggered either by a process control system to which the winding machine and the spinning machine are connected, or by a control computer 12 connected to a control device 11 of the spinning machine RS, which is connected to a reading station 13. The latter is arranged along the second conveyor mechanism 10 and checks the quality data of the data carriers of the cross-wound bobbins KS whether they possibly exceed the predetermined limit values.

Of course, the method according to the invention and the data carrier are not limited to use in composite machines of the type described, but can be used in any type of spinning and winding mill. Since each bobbin wound on a yarn tube provided with a data carrier according to the invention can be completely identified at any time, it can be removed from the production process at any time and subjected to an off-line test. This means that the thread tube with the integrated data carrier is also a valuable aid for off-line testing in the textile laboratory.

The process described is not limited to cotton spinning mills, but can of course also be used for filament and wool production. In addition, it is not limited to spinning / winding, but can be used in the entire yarn manufacturing process. It is likely that the greatest advantages will result if the data carrier according to the invention is used consistently in all stages of yarn production and yarn finishing. It is recommended that the processing stages following the spinning mill also determine quality data and enter them in the data carriers, and that the tubes with the data carriers return to the yarn manufacturer after the yarn has been processed. In this way, he can then create the necessary statistics that form the basis of successful yarn engineering.

The method described has two main advantages:

Since all relevant quality and production data can always be read from each material unit, quality sorting can be carried out at any time and at any point in the production process. This has advantages on the one hand for the producer who can divide his products into quality classes and demand more for good and best quality, and on the other hand for the customer who can buy the products of the different quality classes according to his requirements.

Since no more mistakes can be made, any material unit can be removed from the production process at any time and taken to the textile laboratory for an off-line inspection, where all on-line data are then available. This opens up further possibilities, such as checking and, if necessary, re-calibration of the on-line sensors by the off-line sensors. It is also possible to automate the selection of the material units provided for offline testing by automatically eliminating material units with so-called outliers in the on-line test and making them available for the off-line test or at least specially marking them.

The investigation in the laboratory can be simplified if certain parameters that are important for the handling of the coils, such as, for example, the tube format or the coil dimensions, are also stored on the data carrier. Since the test in the laboratory often does not consume an entire bobbin, but only part of the spooled yarn, you can add them to the laboratory

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Enter the amount of yarn used during the test in the data carrier so that the amount of yarn wound on the relevant bobbin is known. This in turn can have a favorable effect on certain subsequent processes, such as the warping (slip creel with bobbins of the same length).

Finally, and this is not unimportant, the amount of paper is reduced considerably despite the increasing amount of data and the user is encouraged to actually make use of the available data. This is because access to the data is extremely easy and no longer requires working through protocols and forms.

Claims (10)

Claims 1. A method for material identification and data transport in the textile industry, in which each material unit is assigned a machine-writable and readable data carrier, characterized in that the data carrier (3) is arranged directly on the respective material unit (SK, KS) and with quality - and production data is applied, and that between the various stages of the production process, the data mentioned is transferred from one stage to the other, so that the data are available on the entire production process and also during the further processing of the material unit. 2. The method according to claim 1, characterized in that the data carrier (3) is formed by an integrated circuit which contains a memory for machine-inputable data. 3. The method according to claim 2, characterized in that the reading in and reading out of the data in or from the data carrier (3) takes place in a contact-free manner by means of electromagnetic radiation in the high-frequency range, preferably in the microwave range. 4. The method according to claim 3, characterized in that the data stored in the data carrier (3) are secured against access by unauthorized persons. 5. The method according to any one of claims 1 to 4, in which the material units are formed by coils such as flyer coils, spinning bobbins or cross-wound bobbins, characterized in that the data carriers (3) on or in the sleeves (1) of the coils (SK, KS) are arranged. 6. The method according to claim 5, characterized in that the data carrier (3) remains on the sleeve (1) until the winding of the wound yarn (2), and that during rewinding the data of the data carrier together with the data newly created during the rewinding process the old one can be transferred to the new one. 7. Data carrier for performing the method according to claim 1 for material identification and material-accompanying data transport in the textile industry, with a machine-readable and writable data storage, characterized in that the data carrier (3) is arranged directly on the respective material unit and by an integrated circuit with an antenna is formed. 8. Data carrier according to claim 7, characterized by its own intelligence in the form of a microprocessor. 9. A data carrier according to claim 8 for material units formed by coils, characterized in that the data carrier (3) is arranged on or in the sleeves (1) of the coils (SK, KS). 10. Data carrier according to claim 9, characterized by the possibility of contactless data exchange with a read / write device (7, 7 ', 9, 13), the communication protocol and data access being controlled by the microprocessor. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 5