The present invention relates to a method for operating a spinning machine with a multiple number of spinning stations, whereas, during a spinning operation, each of the individual spinning stations is supplied with a fiber material and produces a yarn from this, whereas, upon the occurrence of predefined events, yarn production is interrupted at any or all spinning stations, whereas the spinning stations at which yarn production was interrupted are, when required, spun in with the assistance of a spinning-in process, in order to restart yarn production, and whereas the respective spinning-in process takes place with the assistance of handling devices with their own spinning machines.
Furthermore, a spinning machine with a multiple number of spinning stations for the production of yarn is proposed, whereas each of the spinning stations features at least one spinning unit with an inlet for a fiber material and an outlet for the yarn produced from the fiber material, and whereas each of the spinning stations features a winding device for winding the produced yarn and a yarn monitoring unit for monitoring at least one yarn parameter of the yarn leaving the corresponding spinning unit.
Spinning machines conforming to this type may be formed as, for example, air spinning machines, which are used to produce a yarn from a strand-like fiber material (such as a fiber band) with the assistance of a vortex air flow generated by air nozzles within a vortex chamber. For this purpose, with the assistance of a delivery device, which is preferably formed by a pair of output rollers of a stretching unit upstream of the spinning unit in the direction of spinning, a strand-like fiber material is conveyed in the direction of the spinning unit and is sucked in and sucked out by it through negative pressure. The fiber material ultimately enters the interior of the spinning unit and there in the area of the inlet mouth of a spindle-shaped yarn formation element. The outer fibers of the strand-like fiber material are wound around the inner fibers with the assistance of the vortex air flow in the area of the inlet mouth generated by the air nozzles, such that the result is a stable yarn, which, with the assistance of a draw-off device arranged outside of the spinning unit, is ultimately drawn out through the draw-off channel from the vortex chamber, and is spooled on a sleeve by means of the winding device.
Likewise, the spinning machine in accordance with the invention may also be formed as a so-called “rotor spinning machine,” which is adequately described in the state of the art, the principle of which consists of the fact that the fibers of a likewise strand-shaped fiber material are separated with the assistance of an opening device (usually in the form of an opening roller) and are fed to the rapidly rotating rotor of the spinning unit. Based on the rotor speed, the individual fibers are laid at the inner wall of the rotor, and are thereby twisted into each other. The twisted fibers may ultimately be drawn out through an outlet of the spinning unit and spooled onto a sleeve of a downstream winding device.
If, during the spinning process, spinning errors (non-tolerable hairiness or thick or thin places in the yarn, unsatisfactory supply of fiber material, etc.) arise, or if one or more spinning stations is turned off for a certain period of time, yarn production must be interrupted at the respective spinning station(s). This occurs, for example, by stopping the unit delivering the fiber material into the spinning unit (such as the stretching unit of an air spinning machine) and/or the spinning unit itself. If yarn production is restarted after the stopping of yarn production and, in particular, after the removal of the faulty yarn section, a spinning-in process is necessary at the previously stopped spinning station.
Thereby, the coil-side end of the already produced yarn (that is, the end section of the yarn section last spooled before the interruption of yarn production) is returned counter to the actual spinning direction, and possibly after one or more intermediate steps (for example, a yarn end preparation), through the outlet of the spinning unit, into or through it. Subsequently, the yarn end is brought into contact with the fiber material fed to the spinning unit or the correspondingly fed individual fibers, and is drawn out in the direction of spinning from the spinning unit, Thereby, normal spinning operation is ultimately resumed, with which a yarn is produced from the fiber material fed to the spinning unit.
Generally, it then occurs again and again that a spinning-in process must be carried out at multiple spinning stations simultaneously (for example, during the start-up of the spinning machine, upon which all of the spinning stations must be spun in, or after the interruption of yarn production at multiple spinning stations). Thereby, however, the problem arises that the spinning machine is usually designed to carry out a limited number of simultaneous spinning-in processes. If the spinning-in process is carried out or supported by, for example, by a service unit (a so-called “service robot”) that is movable back and forth along the spinning stations, the number of simultaneously spinning-in spinning stations is limited by the number of service units. Likewise, the number is limited if the spinning-in processes are carried out by spinning-in devices with their own spinning stations, since these have a certain energy and in particular a certain need for compressed air or negative pressure, which can be covered by the spinning machine only up to a certain degree.
Thus, as a result, only a certain number of spinning-in processes can always be carried out simultaneously, whereas it is customary in the state of the art to spin in the spinning stations in the chronological sequence in which they were previously stopped. Even if this approach is quite simple to realize in terms of control technology, there is a need for improvement to reduce the total time required to carry out the spinning-in processes per hour of operation of the spinning machine.
Therefore, the task of this present invention is to improve the described spinning process in such a manner that the efficiency of the spinning machine is improved.
The task is solved by a method and a spinning machine with the characteristics of the independent patent claims.
Within the framework of the method in accordance with the invention, it is now provided that, during the spinning operation of each of the spinning stations, the yarn leaving the spinning units of the individual spinning stations is monitored with the assistance of the yarn monitoring units allocated to the individual spinning stations (for example, by means of sensors monitoring yarn in optical or capacitive terms). The monitored yarn parameters may be, for example, the thickness or the hairiness of the yarn and/or the chronological change of corresponding yarn parameters. If one or more yarn parameters deviates from a given target or if specified limits are exceeded, yarn production is interrupted at the respective spinning station. Likewise, it may be necessary to interrupt yarn production at one or more spinning stations for maintenance or repair purposes. After all of these pre-defined events, it is necessary that the previously stopped spinning station once again spins in, in order to proceed with yarn production.
In contrast to the state of art, the present invention is distinguished by the fact that the individual spinning stations are classified on the basis of one or more production-related parameters (that is, they are assessed qualitatively), and that, if more spinning-in processes are to be carried out simultaneously than can be carried out by the handling devices responsible for the spinning-in (service robots and/or spinning-in devices with their own spinning stations, such as suction or blast nozzles), at least the selection of the spinning station to be spun in next takes place under consideration of the specified classification.
The sequence of the spinning stations to be successively spun in is not governed, or at least not exclusively governed, by the sequence in which yarn production was previously stopped at the respective spinning stations. Rather, for the chronological sequence in which the spinning stations are spun in, the parameters specified or established for the individual spinning stations are taken into account. The parameters are, as explained in more detail below, factors that are determined individually for each spinning station, and with the assistance of which the individual spinning stations can be characterized with respect to their yarn production behavior and/or spinning-in behavior. If the parameters are taken into account upon the selection of the spinning station to be spun in next, the overall time that is required for the spinning-in of the spinning stations of the spinning machine per hour of operation is minimized, and/or the overall efficiency of the spinning machine can be increased.
As a result, therefore, the sequence of the spinning stations that are successively spun in deviates at least partially from the sequence in which yarn production was previously stopped at the respective spinning stations.
Advantageously, if fewer spinning-in processes are currently simultaneously carried out than can be carried out by the handling devices, the selection of the spinning station to be spun in next takes place without consideration of the specified classification. In this case, the individual spinning stations can be spun in, for example, in the chronological sequence in which yarn production was previously stopped at the respective spinning stations. Thus, the chronological sequence of the spinning stations to be successively spun in depends, among other things, on whether, at a specified point in time, more spinning stations are to be spun in than can be spun in by the handling devices provided for this purpose.
In particular, the parameters specified below come into consideration as parameters, whereas one or more of the parameters can be taken into account in the determination of the spinning stations to be successively spun in. At this point, it must be noted that the sequence is preferably specified by a control unit of the spinning machine or a control unit in operative connection with it, whereas, in the specification, the corresponding parameter(s) is or are taken into account; that is, it/they flows/flow into the mathematical model that is saved for this purpose. Thus, the parameters may directly influence the sequence of the spinning stations to be spun in. Alternatively, it would also be possible to calculate one or more parameter(s) or one or more additional parameter(s), and specify the sequence on the basis of the parameter(s) obtained in this manner. In any event, the corresponding parameters for each spinning station should be determined separately, in order to be able to undertake a corresponding individual classification of the spinning stations.
The following are possible as parameters:
It is also advantageous if individual spinning stations are temporarily not spun in, depending on their classification. For example, it would be conceivable to temporarily block spinning stations, for which one or more parameters is outside of defined threshold values, from the spinning-in process. The lifting of the block may take place, for example, after a predetermined time period or manually. Likewise, the blocking of individual spinning stations may take place manually or automatically with the assistance of the control unit, whereas, upon an automatic blocking, a message may be outputted to an operator of the spinning machine (for example, in the form of a visual signal). For example, it would be conceivable to not spin in individual spinning stations for a certain period of time if the number of spinning stations that must be spun in simultaneously exceeds a defined amount, whereas, in such a case, forecasts regarding the spinning-in processes to be expected could be taken into account in a period of time in the future.
It is also extremely advantageous if individual spinning stations are temporarily not spun in, depending on the overall efficiency of the spinning machine. One dimension for assessing the overall efficiency would be, for example, the yarn quantity or yarn length, produced per time unit, averaged through the spinning stations that are not blocked. If the overall efficiency of the spinning machine decreases over time, individual or additional spinning stations can be blocked from the spinning-in process. If the efficiency increases over time, individual or all previously blocked spinning stations could be released again for the spinning-in process.
It is particularly advantageous if the spinning stations that were temporarily not spun in in accordance with the previous description are spun in once again, if the overall efficiency of the spinning machine reaches or exceeds a defined value. In other words, there may be a saving of threshold values, upon the exceeding or falling below of which individual spinning stations are automatically blocked from the spinning-in process or are once again released for it, whereas the selection of the spinning stations to be blocked or once again released is to take place on the basis of the parameters specified above.
It is likewise conceivable to once again spin in individual or all spinning stations that were previously not spun in, depending on the classification that took place, by means of a corresponding control command, for example, if a batch change is pending (that is, a different type of yarn is to be produced on the spinning machine).
It is advantageous if the spinning stations temporarily not spun in in accordance with the previous description are once again spun in, if the number of spinning-in processes that were actually carried out or were requested by the individual spinning stations reaches or falls below a defined value. For example, a value X (for example, 5), which states that up to X spinning stations could be simultaneously spun in, could be saved in the control unit. If, for example, the number of spinning stations to be spun in at a certain point in time is at X+2, 2 spinning stations would be temporarily blocked from the spinning-in process. If, because of successfully carried out spinning-in processes, the number falls once again to a value below the specified value X, additional spinning stations that were previously blocked may be spun in.
It is likewise advantageous if the spinning-in process is carried out at least partially, preferably exclusively, with the assistance of handling devices with their own spinning stations. These include, for example, suction or blowing nozzles or mechanically acting devices, such as gripping elements or pairs of rollers, with which the yarn can be guided or transported.
It may also be advantageous if, in carrying out the spinning-in processes, a service unit (a so-called “service robot”) that is movable back and forth between individual spinning stations is involved, or if the spinning-in processes are carried out exclusively with the assistance of corresponding service units, whereas the movement of the service unit takes place under consideration of the specified classification (whereas, of course, multiple service units may also be used). In other words, the service unit(s) does/do not move, or does/do not always move, to the spinning stations to be spun in, which is at least at a distance from the service unit. Rather, one or more of the parameters specified above of the spinning stations to be spun in are also taken in account, such that the service unit(s) at least partially also initially spins in spinning stations that are further away from the other spinning stations to be spun in.
It is advantageous if the classification of the individual spinning stations takes place on a regular basis; that is, in predetermined time intervals. Preferably, the classification takes place continuously. It is thereby ensured that, for example, spinning stations that have a particularly high rate of production or a particularly reliable spinning-in behavior are preferably spun in. Since the amounts of the monitored parameters may always change, the spinning-in priority of the individual spinning stations (that is, what spinning station is preferably spun in compared to another) may also constantly change.
Finally, the invention relates to a spinning machine with the physical characteristics described above, whereas the spinning machine comprises a control unit or is in operative connection with a control unit that is designed to operate the spinning machine according to the previously described aspects (whereas the aspects may be realized individually or in any combination). In particular, the spinning machine also features sensors, with the assistance of which the parameters considered upon spinning-in can be determined.
The invention is not limited to the illustrated and described embodiments. Variations within the framework of the patent claims, such as any combination of the described characteristics, even if they are illustrated and described in different parts of the description or the claims.
Number | Date | Country | Kind |
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10 2015 110 992.1 | Jul 2015 | DE | national |