DE1185959B - Air-bearing spinning ring - Google Patents

Description

Air-bearing spinning ring The invention relates to a spinning ring, which is rotatably air-mounted in a bearing body of the liftable and lowerable ring rail.

According to a very old suggestion, the air driven spinning ring is on a cylindrical bush of the bearing body with a small radial play rotatably mounted and carries at its one end outside turbine blades inside an annular chamber of the bearing body, which is upward through an annular flange of the after top sliding spinning ring is covered. This allows the exhaust air from the turbine raise the spinning ring a little. The spinning ring is therefore air-bearing in the axial direction. Effective air storage can be achieved in the cylindrical bearing surface of the spinning ring only arise when the spinning ring has reached a high speed. In radial The direction of the spinning ring is aerodynamically air-bearing. Until reaching this Speed, a significant mechanical bearing friction must be overcome, which the Starting difficult. This eliminates the advantage of the axial air bearing.

In contrast, according to the invention, it is only rotating from the thread offset spinning ring by means of compressed air floating aerostatically on all sides in the Storage kept. This makes it possible to use evenly across all storage areas distributed compressed air supply openings an air bearing that is already supported at standstill achieved that does not cause any teething problems. When the air gap is enlarged on one side, e.g. B. by radial displacement of the spinning ring, arises that side immediately decreases air pressure while on the opposite Side forms a higher air pressure causing the immediate return. It So, regardless of whether the spinning ring is rotating or standing still, there will always be one Displacement of the spinning ring, which closes the air gap, so to come about mechanical friction could be counteracted. Under these conditions there is no need to give the spinning ring its own drive. The spinning ring can rather, they are dragged along by the thread to be wound up.

The aerostatically free floating bearing of the spinning ring on all sides can be achieved in that the spinning ring one in the axial direction of both The sides of the ring flange exposed to the internal clearance and a jacket with in radial direction from the outside acted upon by the bearing clearance cylindrical circumferential surface Has. The spinning ring can, however, also take the place of the annular flange and the cylindrical Surface two opposing sides, exposed to the bearing clearance from the outside Have conical surfaces.

The thread tension can be regulated by braking the spinning ring. For this the spinning ring is preferably equipped with an eddy current brake, which by Electromagnet is formed, which in the air supply channels of the bearing surfaces Opposite the spinning ring. Instead, you can also turbine-like on the spinning ring Provide blades that are acted upon by the internal clearance against the direction of rotation of the rotor or suck in air themselves. In the latter case, the in The air from the spinning room is sucked in, but from one fed with fresh air Annular chamber sucked out to prevent clogging of the blade channels by flying fibers avoid. Both types of brakes for rotating spinning rings are known per se.

The invention is illustrated below with reference to in the drawing Embodiments explained.

In Fig. 1, the spinning ring 1 concentrically surrounding the spindle S has a cylindrical jacket 1 a, from which a flat annular flange 1 b extends in the center to the outside. On the raisable and lowerable ring rail 2 3 two annular channels 4 and 5 of rectangular cross section are fastened by means of holders, of which one is above and the other below the annular flange 1 b of the spinning ring is arranged. The fixed ring channels 4 and 5 are connected to a compressed air line in a manner not shown. The inner cylindrical side walls 4 a and 5 a of the ring channels 4 and 5 are the cylindrical shell part 1 a of the spinning ring 1 and the facing end walls 4 b and 5 b of the ring channels 4 and 5 of the annular flange 1 b of the spinning ring with bearing play opposite and have Openings 4 c, 4 d and 5 c, 5 d distributed around the circumference, from which compressed air can flow out against the spinning ring. The air drawn off through the gap spaces keeps the spinning ring from direct contact with the wall surfaces of the air supply channels 4 and 5 on all sides. Since the spinning ring 1 is acted upon by the compressed air on its horizontal annular flange 1 b from above and below and on its cylindrical peripheral surface 1 a in the radial direction, it runs axially as well as radially against an air cushion.

The spinning ring 1 has in the area of its upper edge, which protrudes over the upper edge of the upper air supply channel 4 , a hook-like recess 1 c for pulling the thread F flowing out of the bobbin S from the drafting system (not shown). To avoid an imbalance, two such recesses are expediently provided at points diametrically opposite one another. May be provided on the spinning ring and upwardly projecting hook c in place of the recesses. 1 The thread wound onto the driven spindle S drags the spinning ring with it and gives it a circular motion around the spindle, by means of which the thread experiences a rotation that increases its strength.

In order to be able to exert a braking effect on the spinning ring 1 that is used to regulate the thread tension, in the exemplary embodiment F i g. 1 installed in the air channels 4 and 5 on both sides of the annular flange 16 of the spinning ring electromagnets 6 and 7, which form an eddy current brake. The braking effect can be dosed by changing the excitation of the electromagnets. Once the braking effect has been set, it remains constant - in contrast to braking caused by mechanical friction.

In the embodiment F i g. 2 and 3, the spinning ring 11 also has a cylindrical jacket 11 a, from which a flat annular flange 11 b extends in the middle to the outside. On the outside of the cylinder jacket 11a, blades 11c are provided, the arrangement of which is based on the one shown in FIG. 3 shown partial section along line III-III of F i g. 2 can be seen. With the blades 11 c provided on the cylinder jacket 11 a connected to both end faces of oppositely directed Kegelmätel 11 d on. The at the in F i g. 2 ring rail attached fixed ring body in turn consists of two ring channels 14 and 15 connected to a compressed air source of rectangular cross-section, between the facing end walls 14 6 and 15 b of the ring flange 11 b of the spinning ring 11 engages with bearing play. The inner side walls 14 a and 15 a are opposite to the cylinder jacket 11 a of the spinning ring provided with the blades 11 c. The compressed air flows through openings 14 c, 15 c, 14 d and 15 d of the channel walls 14 a, 15 a and 15 b in the radial direction against the blade ring 11 c and in the axial direction from above and below against the annular flange 11 b of the spinning ring 11. The conical shells 11 d of the spinning ring 11 are tapered collar projections 14 e and 15 e of the annular channels 14 and 15 with bearing play. On the inside of the spinning ring 11, at least one hook 16 protruding freely at the top is provided for pulling the thread through.

The compressed air flowing out of the openings 14 d and 15 d against the annular flange 11 b produces an air cushion which supports the spinning ring 11 in the axial direction. The through openings 14 c and 15 c against the cylinder surface 11 a of the spinning ring outflowing compressed air acts on the blades 11 c, whereby the (g F i. 3) in the direction of arrow 17 rotating spinning ring braking is applied. The compressed air flowing out through the gap between the cone shells 11 d, 14 e and 11 d, 15 e forms an air cushion that acts on the spinning ring both radially and axially.

In the embodiment F i g. 4, the spinning ring 21 also has a cylindrical jacket 21 a and an annular flange 21 b extending from its center, but which is directed inwards here. The cylindrical casing 21 a carries on its inside a ring of blades 21 c, to which cone casing parts 21 d facing each other adjoin on both end faces. The annular flange 21 b engages with bearing play between two annular channels 24 and 25, which are fixedly connected to the annular rail (not shown), for the supply of compressed air. At least one hook 22 protruding freely upward is provided on the edge of the annular flange 21b that extends inwardly through between the air supply ducts 24 and 25 for pulling the thread through.

The annular flange 21 b and the blade ring 21 c opposite wall portions 24 b, 24 a, 25b and 25 a have for the discharge of compressed air to the circumferentially distributed ports 24 c, 24 d, 25 c and 25 d. The conical casing parts 21 d of the spinning ring form, with conical collar projections 26 and 27 of the annular channels 24 and 25, annular gaps through which the compressed air flows outwards, acting radially and axially on the spinning ring. The blades 21 c generate a braking effect. On the outside, around the spinning ring, a jacket 28 firmly connected to the annular channels 25 and 24 is placed, which has slot openings 28 a for the outflow of the compressed air. Behind the slot openings 28 a, a stationary slit diaphragm 29 and a rotatable slit diaphragm 30 are arranged, with which the slot openings 28 a can be adjusted to a smaller width. Further, in the vanes 21 are provided c-carrying cylinder jacket 21 a of the spinning ring 21 apertures 21 e. By this arrangement, it is possible to influence of the braking effect of the vanes 21 c acts on compressed air.

The exemplary embodiment F i g. S agrees with the embodiment F i g with regard to the design of the spinning ring 31 and the compressed air supply channels 34 and 35. 1 to the extent that the air outlet openings 34 c, 34 d, 35 c and 35 d provided in the wall parts 34 a, 34 b, 35 a and 35 b of the air supply ducts 34 and 35 have a cylindrical casing part 31 a and an outwardly extending one from these Opposite annular flange 31 b. For drawing in the thread, at least one hook 32 projecting upward beyond the annular channel 34 is attached to the cylindrical casing part 31 a of the spinning ring. Around the ring channels 34 and 35 carrying the compressed air, two further ring channels 36 and 37 are provided, which are not connected to the compressed air source but to the free atmosphere through a line opening outside the spinning room. The ring flange 31 b of the spinning ring also engages between the ring channels 36 and 37 with bearing play to the outside and there carries a wreath of blades 38 which, as the spinning ring rotates through openings 39 in the walls of the ring channels 36 and 37 facing it, sucks in fresh air and thereby a braking effect is generated. In an outer jacket 40 firmly connected to the stationary ring channels, slot openings 41 are provided for drawing off the compressed air conveyed by the blade ring 38. The air outlet openings 41 are used to regulate the braking effect in the same way as in the exemplary embodiment F i g. 4 adjustable by means of a stationary slit diaphragm 42 and a rotatable slit diaphragm 43.

Claims (7)

Claims: 1. Spinning ring, which is in a bearing body of the lifting and lowerable ring rail is rotatably air-bearing, characterized in that the only Spinning ring (1) set in rotation by the thread aerostatically on all sides by means of compressed air is kept floating in the storage. 2. Spinning ring according to claim 1, characterized in that it has an annular flange (1b) acted upon in the axial direction from both sides by the bearing air and a jacket (1 a) with a cylindrical circumferential surface acted upon in the radial direction from the outside by the bearing air. 3. spinning ring according to claim 1, characterized in that it has two opposing, has conical surfaces (11d) acted upon from the outside by the internal clearance. 4. Spinning ring according to claims 1 to 3, characterized in that it is equipped with an eddy current brake is equipped, which is formed by electromagnets (6 and 7), which in the Air supply channels (4 and 5) are opposite bearing surfaces of the spinning ring. 5. Spinning ring according to claim 1 to 3, characterized in that it is provided with turbine-like blades (11 c, 21 c) which are acted upon by the bearing air against the direction of rotation of the rotor. 6. spinning ring according to claim 5, characterized in that the The blades (38) suck in air themselves. 7. Spinning ring according to claim 6, characterized in that the blades (38) are assigned special fresh air supply channels (36, 37) which are connected to a line opening outside the spinning room. B. spinning ring according to claims 5 to 7, characterized in that air outlet openings (28 a, 41) opening out of an annular channel are provided which are adjustable by diaphragm arrangements (29, 30 or 42, 43). Considered publications: German Patent Specifications Nos. 853 607, 184193, 185134, 179 620; German patent application D 9373 VII / 76c (published on 13 B. 1953); Swiss Patent No. 337 432; French Patent No. 767 024; U.S. Patent No. 2,932,152.