This application claims the benefit of German patent application 10340657.3 filed Sep. 4, 2003, herein incorporated by reference.
The invention relates to an open-end spinning device with a spinning rotor, which can be driven by an individual motor and whose rotor cup rotates in the rotor housing to which an underpressure can be applied and which can be closed by means of a cover element during the spinning process.
Such open-end spinning devices are known in various embodiments in connection with rotor spinning devices and have been described in numerous patent applications.
For example, open-end spinning devices have been known for a long time, wherein the different spinning components are arranged in a spinning box frame which, in turn, has been assembled from several individual components.
These known open-end spinning devices, which have for example been described in German Patent Publication DE 32 47 411 C2, have a spinning box frame which consists of at least two lateral frames, which can be fixed in place on the base element of a spinning device, at least two upper bracing elements, as well as at least one lower spacing device.
Here, the lateral frames and the bracing elements are connected with each other by means of a plurality of threaded bolts, wherein the individual components are aligned via fitting bore/fitting pin connections in an elaborate manner.
In connection with such open-end spinning devices, the large number of fitting bores which are required to exactly connect the spinning box frame is disadvantageous inter alia. Moreover, in regard to screw connections there is always the danger that they come loose over time because of the vibrations during the running of the textile machine.
This means that no sufficient rigidity of a spinning box frame with screw connections of this type can be assured over time which, in addition to the rotor seating, must contain the sliver opening device, as well as a cover element for closing off the rotor housing during the spinning operations.
To avoid the above mentioned disadvantages, a shift has been made toward the permanent connection of the various components of such spinning box frames by arc welding.
However, with arc welding there is the danger that, because of heating over large surfaces of the parts to be welded together, warping as a result of thermal stressing of the individual components can occur. The components must therefore be aligned again after welding before the bores for the fitted alignment of the various spinning components can be drilled.
For avoiding such thermal stresses because of heating it has already been proposed to connect the individual components of the spinning box frame by laser welding. German Patent Publication DE 19717 737 A1 describes such spinning box frames, whose components have been connected by means of a laser connecting process.
Since with this method the energy used can be exactly metered, and the area of heat supply can be very exactly localized, no heat effects over large areas of the involved components arise. No warping of the spinning box frame occurs with this method.
However, a spinning box frame by itself already constitutes a relatively expensive component, which is merely used for seating the various spinning components of an open-end spinning device in an exactly positioned manner and for fixing it in place on a machine frame of a textile machine. It has therefore already been attempted in the past to position the spinning components of an open-end spinning device on a textile machine without a special spinning box frame being employed.
German Patent Publication DE 2130 688 A1 describes such an open-end spinning device.
With this known open-end spinning device, the spinning components, some of which are independent of each other to the greatest extent, have been mounted directly on a linear support of the machine base frame of a textile machine. In this case the rotor housing is fixed in place on the upper leg of a U-shaped leg by means of lateral flanges and has a rear cutout, in which a spinning rotor driven by a single motor is seated.
The front of the rotor housing can be closed by means of a cover, which in turn is pivotably seated on the rotor housing.
A sliver opening device is fastened, spaced apart from the rotor housing, on the front of the lower leg of the U-shaped support and is functionally connected with the rotor housing via a fiber guide channel.
However, the selected separated arrangement of the spinning components has not shown itself to be very advantageous during the spinning operation, so that these known open-end spinning devices were never capable of being accepted in actual use.
Based on the above mentioned prior art, it is the object of the instant invention to develop an open-end spinning device which, on the one hand, can be produced in a cost-effective manner, and by means of which, on the other hand, it is assured that the different spinning components can be exactly positioned.
This object of the invention is attained by means of an open-end spinning device basically having a spinning rotor, which can be driven by an individual motor and whose rotor cup rotates in the rotor housing to which an underpressure can be applied and which can be closed by means of a cover element during the spinning process. According to the present invention, the rotor housing is embodied as a central component, which can be fixed in place on the machine frame of a textile machine, to which the drive mechanism of the spinning rotor, as well as a cover element having supports for a sliver opening device can be connected.
Advantageous embodiments of the invention are described below.
By embodying the rotor housing in the form of a central supporting component, the embodiment in accordance with the invention has the advantage that it possible to completely do without a complex spinning box frame for positioning the various spinning components.
This means that in accordance with the present invention the rotor housing, which can be fixed in place releasably on the machine frame of the textile machine, for example by means of fastening tongues, constitutes the bearing backbone of the open-end spinning device in accordance with the invention, to which the other spinning components are attached.
The single-motor drive mechanism for the spinning rotor is directly screwed on the rotor housing which rotor housing is preferably embodied as a cast part made of a metallic material with good heat conductivity. Such an arrangement furthermore has the advantage that the conveying air which pneumatically transports the fibers from the opening device to the spinning rotor and flows through the rotor housing, simultaneously also cools the drive mechanism of the spinning rotor.
Since furthermore the supports for a cover element having a sliver opening device are fastened on the rotor housing, the embodiment in accordance with the invention as a whole represents a cost-effective and extremely compact construction.
The embodiment in accordance with the invention also assures that the spatial association of the individual spinning components is most accurately maintained and, for example during an exchange of individual spinning components, is reproducible at any time which, in the interest of a good spinning results, is extremely important.
As already indicated above, the rotor housing in an advantageous embodiment is preferably designed as a cast element, wherein aluminum, for example, is used as a preferred metallic material. Such a manufacturing process makes it possible to produce mass-produced parts in particular, cost effectively and exactly fitted.
The embodiment with a magnetic bearing for the spinning rotor which is seated in a contactless manner integrated into the rotor housing, has proven itself to be extremely advantageous.
By means of such an arrangement it is assured in a simple way that the spinning rotor always takes up an exactly defined position in relation to the rotor housing.
In this case no adjustment work or the like is necessary when installing the spinning rotor.
The housing of the electromagnetic drive mechanism of the spinning rotor, which also contains the rear magnetic bearing for the spinning rotor, can be fixed in place on the rotor housing via threaded bolts, which penetrate the rear wall of the motor housing from the front.
The front magnetic bearing integrated into the rotor housing at the same time constitutes a centering shoulder, on which the housing of the drive mechanism of the spinning rotor can be exactly positioned.
A housing for the electronic control device of the spinning rotor drive mechanism is furthermore provided. This housing is directly connected with the housing of the spinning rotor drive mechanism.
The construction of the open-end spinning device which, as a whole, is very compact, is also aided by means of this arrangement.
In an advantageous embodiment the supports on which the cover element having the sliver opening device is seated, limited in some degree and removable, are also produced as cast elements. As already described above in connection with the rotor housing, such a manufacturing process offers the chance of producing mass-produced elements with exact fit and cost-effectively.
The supports, which can be fixed in place on the rotor housing, preferably consist of a metallic material, for example aluminum.
In this case the separately produced supports, which are provided with fitting bores, can be fixed in place on the rotor housing by means of appropriate centering pins, as well as threaded bolts in an exactly fitted way, and then constitute a quasi one-piece element together with the rotor housing, with a pivot axis exactly positioned in respect to the spinning rotor shaft.
Therefore the spinning components arranged in the cover element can also always be exactly positioned in respect to the spinning rotor shaft.
The sliding bushings arranged in corresponding bearings of the supports correspond in a known manner to adjustable journals on the cover element and thus make possible easy pivoting of the cover element into the open and closed position, as well as also a rapid and problem-free exchange of this component when needed.
The invention will be explained in what follows by means of an exemplary embodiment represented in the drawings.
Shown are in:
The open-end spinning device in accordance with the invention is represented in several views in
As the central supporting component, the open-end spinning device 1 has a rotor housing 2 made of a metal with good heat conducting properties, for example aluminum, on which exactly fitting supports 4 have been fixed in place by means of fitting bolts 16, or threaded bolts 17. On their ends, these supports 4, each designed for example as bearing arms, have a bearing equipped with sliding bushings 28, which constitute a pivot shaft 5 a cover element 6.
The cover element 6, which closes the rotor housing 6 during spinning operations, has an annular seal 22 for this purpose, which rests against the front wall of the rotor housing 2.
A sliver opening device 23 is furthermore integrated into the cover element 6 which has, as schematically indicated, an opening roller 7 driven by an individual motor, as well as a sliver draw-in cylinder 8, also driven by an individual motor.
Moreover, the housing of the drive mechanism 3 for the spinning rotor 21, whose rotor cup rotates in the rotor housing 2 to which an underpressure can be applied, has been fixed in place on the rear 26 of the rotor housing 2.
Here, the spinning rotor 21, which is driven by an individual motor, is supported in a contactless manner by means of magnetic bearings 24, 25.
Such spinning rotors, driven and seated in this manner, are known in principle and have been described relatively extensively, for example in EP 0 972 868 A2.
A housing 14 is connected to the housing of the spinning rotor drive mechanism 3, which contains the electronic control device 15 for the drive mechanism 3. In this case the electronic control device 15 assures that the spinning rotor 21 always rotates at a prescribed number of revolutions. The rotor housing 2 is furthermore connected in the customary manner via a pneumatic line 10 to a (not represented) underpressure source, which makes the underpressure needed during the spinning process available.
As indicated in
The yarn (not represented) produced during the spinning process in the open-end spinning device 1 is drawn-off the open-end spinning device 1 through a small yarn draw-off tube 9 and is subsequently wound into a cheese by means of a known winding device (not represented).
As can be furthermore seen from
A rear view of the open-end spinning device 1 in accordance with the invention is represented in
Moreover, the drive mechanism 3 for the spinning rotor 21 can be seen on the rear wall 26 of the rotor housing, which in turn is connected with the housing 14 for the electronic control device 15.
The rear wall of the cover element 6 is visible below the drive mechanism 3. The individual drive mechanism 18 for the sliver draw-in cylinder 8, as well as the bearing bracket 20 for the opening roller 7 embodied as an external roller, are arranged at this rear wall of the cover element 6.
As can be seen, in the outer area of the rear of the rotor housing 2, supports 4 have been exactly fitted in place by fitting pins 16, or threaded bolts 17.
As furthermore indicated, bores have been furthermore inserted in the rear wall 26 of the rotor housing 2 in the area of the centering shoulder 29, in which threaded bolts 27 can be fixed in place, which arrest the drive mechanism 3 of the spinning rotor 21 in place on the rotor housing 2.
Number | Date | Country | Kind |
---|---|---|---|
103 40 657 | Sep 2003 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2004/007341 | 7/6/2004 | WO | 00 | 2/28/2006 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2005/033385 | 4/14/2005 | WO | A |
Number | Name | Date | Kind |
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3922840 | Watanabe et al. | Dec 1975 | A |
3972171 | Handschuch et al. | Aug 1976 | A |
4122655 | Anderson et al. | Oct 1978 | A |
4516396 | Stahlecker et al. | May 1985 | A |
5647196 | Wassenhoven | Jul 1997 | A |
5755087 | Biller et al. | May 1998 | A |
6082090 | Wassenhoven et al. | Jul 2000 | A |
6124658 | Coenen | Sep 2000 | A |
20020033013 | Wassenhoven | Mar 2002 | A1 |
Number | Date | Country |
---|---|---|
21 30 688 | Jan 1973 | DE |
3247411 | Jun 1984 | DE |
197 17 737 | Oct 1998 | DE |
EP 0 972 868 | Jan 2000 | DE |
EP 1 188 850 | Mar 2002 | DE |
Number | Date | Country | |
---|---|---|---|
20070130908 A1 | Jun 2007 | US |