For an air spinning frame, reluctance motors are provided for each spinning place to drive the pairs of rollers of the drafting unit, the drawing-off means, and the friction roller. Thereby, for the run-up of a spinning place, e.g., after a thread break, a specific frequency converter is provided. A
For an air spinning frame, reluctance motors are provided for each spinning place to drive the pairs of rollers of the drafting unit, the drawing-off means, and the friction roller. Thereby, for the run-up of a spinning place, e.g., after a thread break, a specific frequency converter is provided. After reaching the stationary operating speed, a switch over onto a further frequency converter takes place, at which time, the corresponding reluctance motors of the other spinning places are driven in parallel. By the use of reluctance motors it can be done without a complex speed regulation means. A specific dimensioning of the reluctance motors permits a very fast run-up and a particularly good efficiency during the stationary operation.
대표청구항▼
The invention claimed is: 1. An air spinning frame having a plurality of spinning places for the production of spun thread from a supplied longitudinal fiber formation, each of said spinning places comprising: a drafting unit having at least two pairs of drafting rollers, said drafting units drafti
The invention claimed is: 1. An air spinning frame having a plurality of spinning places for the production of spun thread from a supplied longitudinal fiber formation, each of said spinning places comprising: a drafting unit having at least two pairs of drafting rollers, said drafting units drafting said longitudinal fiber formation; a pair of drawing-off rollers positioned downstream from said drafting unit in a direction of travel of a formed thread created from fibers discharged from said drafting unit, said pair of drawing-off rollers transporting said thread after the formation of said thread; a friction roller positioned downstream from said pair of drawing-off rollers in the direction of travel of said thread, said friction roller driving a yarn package to wind said thread onto said yarn package; a plurality of electrically driven reluctance motors operably connected to said pairs of drafting rollers, said pair of drawing-off rollers, and said friction roller, said reluctance motors driving said pairs of drafting rollers, said pair of drawing-off rollers and said friction roller; and a plurality of frequency converters with at least one of said frequency converters operably connectable to each of said reluctance motors by a respective switch. 2. An air spinning frame having a plurality of spinning places for the production of spun thread from a supplied longitudinal fiber formation, each of said spinning places comprising: a drafting unit having at least two pairs of drafting rollers, said drafting units drafting said longitudinal fiber formation; a pair of drawing-off rollers positioned downstream from said drafting unit in a direction of travel of a formed thread created from fibers discharged from said drafting unit, said pair of drawing-off rollers transporting said thread after the formation of said thread; a friction roller positioned downstream from said pair of drawing-off rollers in the direction of travel of said thread, said friction roller driving a yarn package to wind said thread onto said yarn package; a plurality of electrically driven reluctance motors operably connected to said pairs of drafting rollers, said pair of drawing-off rollers, and said friction roller, said reluctance motors driving said pairs of drafting rollers, said pair of drawing-off rollers and said friction roller; a plurality of frequency converters with at least one of said frequency converters operably connectable to each of said reluctance motors by a respective switch; and wherein said plurality of frequency converters comprises a plurality of first frequency converters and a plurality of second frequency converters with one of said first frequency converters and one of said second frequency converters operably connectable to each of said reluctance motors by said respective switch. 3. An air spinning frame as in claim 2, wherein said switches connect said second frequency converters to said reluctance motors during a stationary mode of operation for each of said reluctance motors and said switches connect said first frequency converters to said reluctance motors for a run-up mode for each of said reluctance motors. 4. An air spinning frame as in claim 3, wherein corresponding said reluctance motors of said plurality of spinning places are connected in parallel when said switches connect said second frequency converters to said reluctance motors. 5. An air spinning frame as in claim 1, wherein said switches comprise at least one of electronic switches or galvanic switches. 6. An air spinning frame as in claim 2, wherein said switches comprise a coupling for the controlling of a timed sequence of a switch over of each of said reluctance motors from a corresponding said first frequency converter to a corresponding said second frequency converter. 7. An air spinning frame as in claim 1, wherein an operating point of each of said reluctance motors is below a nominal point. 8. An air spinning frame as in claim 7, wherein a current intensity corresponding to the operating point is about 0.67 times a current intensity corresponding to said nominal point. 9. An air spinning frame as in claim 2, wherein said second frequency converters for each of said reluctance motors within said spinning place are connected by a common direct intermediate circuit. 10. An air spinning frame as in claim 1, wherein stators of said reluctance motors comprise a water cooling unit. 11. A method of operation of an air spinning frame having a plurality of spinning places for the production of spun thread from a supplied longitudinal fiber formation, the method comprising of the steps: driving pairs of drafting rollers, a pair of drawing-off rollers and a friction roller by a plurality of reluctance motors within a spinning place; connecting each of the reluctance motors within the spinning place to a corresponding first frequency converter with an assigned switch to run up the speeds of each of the reluctance motors to a predetermined speed proximal to a stationary operating speed for each of the reluctance motors; and switching each of the reluctance motors within the spinning place from the corresponding first frequency converter to a corresponding second frequency converter with the assigned switch once the speeds of each of the reluctance motors reach the respective predetermined speeds to run the reluctance motors at the stationary operating speeds for each of the reluctance motors. 12. A method as in claim 11, wherein the reluctance motors within the spinning place run-up synchronously to a supplied frequency based on a constant voltage-frequency ratio. 13. A method as in claim 11, wherein the speed reached during run-up for the reluctance motor for the drive of the pair of draw-off rollers is higher than the stationary operating speed for that reluctance motor to avoid thread tensioning. 14. A method as in claim 11, wherein the point in time of the switching of the reluctance motor for the drive of the friction roller from the corresponding first converter to the corresponding second converter for that reluctance motor lies before the point in time of the switching of the reluctance motor for the drive of the pair of draw-off rollers from the corresponding first converter to the corresponding second converter for that reluctance motor to avoid thread tensioning. 15. A method as in claim 11, wherein, after switching from the corresponding first converter to the corresponding second converter for the reluctance motors, each of the reluctance motors run-up to the stationary operating speed of that reluctance motor in a non-synchronous manner compared to the run-up of the other reluctance motors. 16. A method as in claim 11, wherein the second frequency converters for each of the reluctance motors within the spinning place are connected by a common direct intermediate circuit. 17. A method as in claim 16, wherein the second frequency converters are capable of a four-quadrant operation. 18. A method as in claim 17, wherein, during a power supply failure, the reluctance motor driving the friction roller at each spinning place acts as a generator and supplies generated electrical power to the reluctance motors driving the pair of drafting rollers and the pair of draw-off rollers to drive the air spinning frame during run down in a controlled manner to avoid thread breaks. 19. A method as in claim 18, wherein the direct current intermediate circuit is held at a constant voltage during run down of the air spinning frame.
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이 특허에 인용된 특허 (9)
Hartmannsgruber Max (Kirchheim DEX) Wolf Horst (Albershausen DEX), Driving assembly for ring spinning or twisting machine.
Baeumel Hermann,DEX ; Kilian Hermann,DEX ; Schuch Bernhard,DEX ; Bitsche Otmar,DEX, Integrated electric drive unit including an electric motor and an electronic control and monitoring module.
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