DE2403965A1 - Open-end spinning rotor support - uses air cushions and additional bearings at point of maximum rotor diameter - Google Patents

Abstract

A bearing mounting system for the rotor of an open-end spinning unit, where the bearing action has a pneumatic shroud for support and friction-free running, uses additional radial supports located at right angles to the rotor axis and the centre of gravity of the rotor, these supports being mounted where the rotor is at its maximum diameter. The design provides support for the rotor at the point of maximum stress from its belt drive, preventing any imbalance in running, and allowing a simple air cushion system for the support of the mass of the rotor shaft.

Description

Storage of spinning rotors using the open-end method Spinning machines The invention relates to a mounting of spinning rotors according to the open-end method working spinning machines, in which the essentially sc'neiben-shaped Spinning rotor - he twisted over the associated rotor shaft with a drive device is - in the axial and radial direction on gas cushions built up in support pockets supported on the stationary environment.

The use of gas bearings to support spinning rotors is already in place known. The rotor shaft connected to the spinning motor is in two storage levels in the radial direction and for axial fixation in a further storage plane held.

The support of the spinning rotor corresponds to three different levels the usual design for normal camps.

The invention is based on the task of a gas bearing for spinning rotors to develop, which is less expensive to set up than the previously known gas bearings.

The problem is solved by the fact that the storage forming facilities at least in the immediate vicinity of the perpendicular to the rotor axis of rotation lying focal plane of the spinning rotor are arranged, with its support essentially only about those in the area of its largest diameter Areas, d.f. in the area of the rotor disk. The rotor shaft is one Associated device, which exercised by the drive device, transversely to The rotor axis absorbs forces.

The essence of the invention consists in the fact that the spinning rotor - apart from the fixation in the axial direction - mounted radially only in one plane is.

This is possible because of the essentially writing-shaped spinning rotor moves around an axis of rotation, with respect to which its moment of inertia is greatest Has value.

The support of the spinning rotor in the area of the rotor disk is above it In addition, it enables the spinning technology tasks of the spinning rotor can only be filled by its inner surfaces.

The gas storage can therefore be constructed in a particularly simple manner.

The device through which the forces transverse to the rotor axis are balanced, consists advantageously of three mutually offset, stationary support rollers on which the part of the rotor shaft -which with the drive facility is connected - rests in lines.

In another preferred embodiment of the subject matter of the invention are upstream and downstream of the rotor shaft with guide rollers, which guide the Upper and Lower run of the drive belt serving as a drive device form, with the ODer- and the lower run the rotor shaft on them with respect to this wrap opposite sides at a small angle.

In a further embodiment of the subject matter of the invention is serve Rotor shaft connected to a Xardangelenk arrangement consisting of several concentric ring parts, the outer ring of which is in contact with the drive device.

To ensure the axial and radial fixation of the spinning rotor consist the devices forming the bearing advantageously from a ring radially arranged and two rings arranged on both sides of the plane of the center of gravity axial support pockets.

However, the means forming the storage may preferably also consist of two rings of support pockets, which are at least approximately the same Angle - viewed from the plane of the center of gravity - with respect to the plane of the center of gravity are inclined. The opposing support pocket rings take both axial as well as radial force components.

To improve the damping and vibration properties of the gas bearing the support pockets are at least partially filled with porous material.

The gas supply bores connected to the support pockets advantageously have a cross section which is smaller than that present in the area of the sealing surfaces Leak cross-section between the spinning rotor and the stationary environment.

The gas supply bores consequently act as throttling points which pressure fluctuations in the Sas supply system are reduced.

In many cases it is particularly advantageous not to use the support pockets only in the rotor housing that forms the stationary environment, but also partially to be attached in the rotor disc.

The restoring forces resulting from the displacement of the spinning rotor can thereby be shifted to a certain degree in internal I? iiase. In particular it is possible to let the restoring forces advance, as is done to compensate of the precession moments resulting from the gyratory motion of the spinning rotor is.

In a further embodiment of the subject matter of the invention, the gas storage be designed so that there is a pressure in the support pockets that is at least corresponds to the pressure of the external environment, while the pressure surrounding the spinning rotor is less than the pressure of the outside environment. If the spinning rotor is in a sub The environment under pressure is working, so it is sufficient to reduce the gas pressure in the support pockets to be kept slightly above atmospheric pressure.

The operational safety of the gas storage is improved in that the spinning rotor made of particularly light material, such as fiber-reinforced Plastic or light metal alloys is made.

Further essential features and properties of the subject matter of the invention are described below with reference to the exemplary embodiments shown in the drawing explained.

It shows: lilig. 1 shows a section through the gas bearing of a spinning rotor, which has a ring of radial support pockets and two rings of axial support pockets that are opposite to the rotor disk, FIG. 2 shows a section along the line II-II in FIG. 1, FIG Section through a gas storage system in which the opposing surfaces of the spinning rotor and the housing are conical, FIG. 4 is a view in the direction of arrow IV (without housing and opening roller) according to FIG. 3, 5 schematically shows a drive arrangement of the spinning rotor in which the rotor shaft is connected to a drive belt with the interposition of a sardangle arrangement, FIG. 6 shows a drive arrangement in which the drive belt is supported on guide rollers, and FIG Arrangement in which the rotor shaft is held by several support rollers. The open-end spinning device has a rotor 1 with the rotor shaft 19 and a dissolving housing 2 projecting partially into the opening of the spinning rotor 1 with a feed bore 2 'and a deflecting shoulder 2 ".

The barrel material 3 to be processed passes through the feed bore 2 'on the inner surface 1 ″ of the spinning rotor 1, collects in the so-called fiber collecting trough 1? of the spinning rotor and is from there by the coaxially arranged, stationary Exit tube 4 as a finished thread 5 by means of take-off rollers 6 moving in opposite directions deducted.

The direction of movement of the bath 5 is indicated by the arrow 7.

The spinning rotor 1 is arranged in a housing 8, which consists of two housing parts 8 'and 8 "closely connected to one another. The outlet pipe 4 is attached to a housing 9, which in turn is sealed with the housing part 8 ″ is screwed.

In the inner surfaces of the housing 8 facing the spinning rotor three rings of support pockets 10, 11 and 12 are arranged. The end faces of the spinning rotor opposite support pockets 10 and 11 are used for axial fixation, while the support tabs 12 of the radial ones opposite the circumferential surface of the rotor disk Serve fixation of the spinning rotor 1.

That which is required to generate the supporting forces and which is under pressure Gas is fed from the outside through a line 13 to an annular channel 14 and via this through throttle bores 15 and bores 16 extending from the annular channel and with these connected throttle bores 17 and 18 supplied to the individual support brackets.

The sealing of the support pockets against each other or against the environment takes place by means of sealing surfaces 50 to 52.

The radial support pockets 12 are different from the axial support pockets 10 and 11 additionally separated by annular grooves 19 and vent holes 20 (FIG. 2).

Another embodiment of the radial and axial support pockets 10 to 12 is shown in the lower half of FIG. In this case the pressure-related separation of the axial and radial support pockets only over enlarged Sealing surfaces 21.

The spinning rotor 1 is over a drive belt 22, which the rotor shaft 12 partially wrapped around, with a drive device - for example an electric motor -in connection. The through the drive belt on the rotor shaft 1 'and thus on the The transverse forces exerted by the spinning rotor 1 are at least partially grounded by supporting rollers running along with them 23 recorded, on which sicr the rotor shaft 1 'is supported. The support rollers 23, which are fixedly connected to the housing 9 via a pin 24 have An elastic base layer 25 on its peripheral surface. This stands with the rotor shaft 1 'in linear contact. (For the sake of clarity, there is only one support role shown, offset, see Fig. 7.) To improve the damping and the vibration properties of the gas bearing are the support pockets 10 to 12 with porous material such as sintered bronze or porous polytetrafluoroethylene filled out.

In another embodiment of the subject matter of the invention (Fig. 3, 4) the spinning rotor 1 has conical peripheral surfaces 27 and 28, which compared to the Storage level 29 vertical to the axis of rotation 30 approximately below the same Angles are inclined. The surfaces 27 and 28 are correspondingly inclined surfaces 31 or 32 of the housing 2 with a distance opposite.

Deviating from the previously described embodiment are in these Case support pockets 3); mounted in the surfaces 27 and 28 of the spinning rotor i.

The pressurized gas is through an annular channel 34 - which is tightly connected to the housing 2 - and bores extending from the annular channel 34 35 supplied. Throttle bores 36, the outlet opening of which extend from the bores 35 the support pockets 33 is opposite.

The diameter of the throttle bores 36 is dimensioned so that an optimal support of the spinning rotor on the housing surfaces 31 and 32 results. The cross section of the throttle bores 36 should not be larger than the cross section which results from the distance "1" between the surfaces 27 and 31 or 28 and 32 and the Around the length of a support pocket 33 results.

The support pockets of surface 27 are different from those of surface 28 in terms of pressure separated by an annular groove 37, which communicates with the environment via a ventilation hole 37t communicates.

The spinning rotor 1 is driven in the manner already described Way by means of a drive belt 22, which expediently simultaneously for several Rotor shafts 1 'is used. These are only weak, i.e. over a few Degrees wrapped around (Fig. 6).

The return run of the drive belt is used to compensate for the belt forces - with the interposition of guide rollers 44 - also loosely wrapped around passed the rotor shafts.

The return of the drive belt - the one in the direction of arrow 45 is driven - takes place by means of the stationary pulley 46. This is useful arranged displaceably in the direction of the longitudinal axis 47 of the drive device, for example by means of a threaded rod that can be screwed against a stop 48 49, which is connected to the axis of rotation of the deflection roller 46.

To generate the effects of the drive belt 22, transversely to the rotor axis To avoid 1 "" directed forces on the rotor disk, you can move the rotor shaft 1 'also with the interposition of a universal joint arrangement with a pulley 38 connect, which for better guidance of the drive belt 22 with side walls 38t is provided (Fig. 5).

The rotor shaft 19 is in this embodiment via bearing journals 39 in an intermediate ring 40 held, which in turn via bearing cams 41 in the pulley 38 is pivotable.

The pivot axis formed by the bearing pin 39 is opposite the pivot axis formed by the bearing pin 41 offset by 90 °.

The universal joint arrangement ensures the free movement of the the rotor shaft 1 'connected rotor disk in perpendicular and horizontal direction.

The drive belt 22 is set in motion by a drive pulley 42, which is attached to the shaft of a sheet metal motor 43.

The transverse forces exerted by the drive belt 22 can also be caused by several - advantageously three - support rollers 23 are added against each other are arranged offset (Fig. 7).

The support rollers touch the outer contour of the rotor shaft 1 while the drive belt lies in a guide groove on the rotor shaft, i.e. without contact.

moved on under the parts 23.

Patent claims:

Claims (12)

P a t e n t a n s n r ü c h e 1 Storage of spinning rotors according to the Open-end process of working spinning machines, in which the essentially disc-shaped spinning rotor - the one via the associated rotor shaft with a drive device is connected - in the axial and radial directions on built-up in support bases.l Gas cushions supported on the stationary environment, characterized in that the the storage forming facilities at least in the immediate vicinity of the vertical to the rotor axis of rotation (1 "") lying focal plane of the spinning rotor (1) are, the support of which is essentially only in the area of its largest Diameter, i.e. in the area of the rotor disk. 2. Storage according to claim 1, characterized in that the rotor shaft (1?) A device is assigned which is exercised by the drive device, at least partially absorbs forces lying transversely to the rotor axis (1 ""). 3. Storage according to claim 2, characterized in that the device consists of three mutually offset stationary support rollers (23) on which the part of the rotor shaft (1 ') - which is connected to the drive device stands - rests in lines. 4. Storage according to claim 2, characterized in that the rotor shaft (1s) upstream and downstream guide rollers (44), which guide the upper and Lower run of the drive belt serving as the drive device Form (22), the upper and lower run of the rotor shaft (1 ') with respect to each other wrap these opposite sides at a small angle. 5. Storage according to the preceding claims, characterized in that that the rotor shaft (1 ') with one of several concentric ring parts (38,40) existing universal joint arrangement is connected, the outer ring (38) with the drive device is in contact. 6. Storage according to one or more of claims 1 to 5, characterized characterized in that the devices forming the bearing consist of a ring radially arranged and two rings arranged on both sides of the plane of the center of gravity axial support pockets (12 or 10, 11) exist. 7. Storage according to one or more of claims 1 to 5, characterized characterized in that the devices forming the bearing consist of two rings of Support pockets (33) exist, which are at least at approximately the same angle - of viewed from the plane of the center of gravity - are inclined with respect to the plane of the center of gravity. 8. Storage according to one or more of the preceding claims, characterized in that the support pockets (10 to 12 or 33) at least partially are filled with porous material (26). 9. Storage according to one or more of the preceding claims, characterized in that the with connected to the support pockets Gas supply bores have a cross section which is smaller than that in Leakage cross-section between the spinning rotor (1) in the area of the sealing surfaces and the stationary environment. 10. Storage according to one or more of the preceding claims, characterized in that the support pockets are at least partially in the stationary Surrounding forming rotor housing (2) are attached. 11. Storage according to one or more of the preceding claims, characterized in that the support pockets are at least partially in the rotor disk are appropriate. 12. Storage according to one or more of the preceding claims, characterized in that there is a pressure in the support pockets which is at least corresponds to the pressure of the external environment, while that surrounding the spinning rotor (1) Pressure is lower than the pressure of the outside environment.