DE19804868A1 - Support disk for shaft of spinning rotor - Google Patents

Abstract

The support disk, for the shaft of a spinning rotor, is surrounded by a carrier ring with a polymer support ring injection molded round its circumference. The outer circumference of the carrier ring has at least one radial projection (4) with at least one recess (6) at its side towards the outer periphery. The projection (4) has a passage opening (6) through it, wholly filled by the polymer material of the support ring. The radial projection (4) has consistent and irregular passage openings through it. Each passage opening (6) has a recess extending radially inwards. The recess (6) is formed by a groove (7) at the peripheral side round the circumference, open radially outwards. The base (8) of the groove (7) is penetrated by the passage openings. The groove (7) has a rectangular cross-section, with a depth (9) matching the height (10) of the radial projection (4). The radial projection (4) has end sides (11,12) axially on both sides with at least one closed ring groove in contact with projections from the support disk (3). The passage openings link the ring grooves together in the axial direction. The support disk (3) has a radial U-profile, open inwards, to give a clip grip over the radial projection (4).

Description

Technical field

The invention relates to a support disc for mounting a rotor Open-end spinning machine comprising a support ring and one on top of it Outer circumference specified support ring made of polymeric material, the Support ring and the support ring are positively connected, wherein the outer circumference of the support ring has at least one radial projection, which is penetrated in the axial direction by at least one opening and wherein the opening of the polymeric material of the support ring is completely filled out.

State of the art

Such a support disc is known from DE 41 36 793 C1. Of the The outer circumference of the support ring has an essentially double-T-shaped profile on that of the radially inward open U-shaped profile of the support ring is encompassed. The double T-shaped profile of the support ring is even in Circumferential openings penetrated to a to achieve improved interlocking of support ring and support ring to each other and an undesirable even under unfavorable operating conditions  exclude mutual separation of the two parts from each other. Here However, it should be noted that the manufacture of the known support disc in Injection molding is difficult to perform. In the field of positive clawing of the support ring and support ring occurs when Injecting the polymeric material often to trap air, thereby following the curing of the support ring blowholes within the polymer Material remain. Such blowholes occur in particular, depending on the Flow front in the area of undercuts and / or sharp-edged Limits of the support ring.

Presentation of the invention

The invention has for its object a support disc of the beginning mentioned type to develop in such a way that an improved Producibility results from an improved filling and venting behavior and thereby the formation of voids and the resulting Imbalance is safely avoided during use of the support disc.

This object is achieved with the features of claim 1 solved. The subclaims refer to advantageous refinements.

To solve the problem it is provided that the radial projection is provided on the outer circumference with at least one recess, which is in the breakthrough extends. The advantage here is that in the manufacture the support disc, for example in the preferred injection molding process, the Risk of air trapping in the polymeric material, especially in the Area of undercuts of the support ring and / or sharp-edged Limits is limited to a negligible level. The good Producibility and good filling and venting behavior is independent of the flow fronts of the polymer material with which the support ring is molded  becomes. With the central flow front, the flowable polymer material only becomes on the outer circumference on the support ring and thus in the recesses injected, the air to be displaced from the recess through the Breakthrough is displaced towards the atmosphere.

In contrast, if the flowable polymeric material is in the range of End faces of the support ring in the end boundaries of the opening The air is fed in from the opening through the recess displaced while the injection mold with polymeric material Manufacture of the support ring fills. Due to the shape of the support ring Committee in the manufacture of the support disc significantly reduced. Thereby, that the rotor to be supported has speeds of up to 150,000 revolutions / min is achieved, the support disk runs absolutely without any imbalance absolutely necessary. In view of this, a support ring is without voids a noteworthy advantage.

The radial projection is preferably uniform in the circumferential direction distributed breakthroughs. At least eight are preferred Breakthroughs for use. Eight evenly in the circumferential direction distributed breakthroughs have proven to be an excellent compromise between manufacturing costs for introducing the openings in the Radial projection on the one hand and void-free injection of the polymer Proven material for the production of the support ring on the other hand.

According to a first embodiment, there is the possibility that in each Breakthrough one, essentially in the radial direction to the inside extending recess opens. The recesses can, for example be formed by bores.  

To achieve a simplified and economical according to a second, advantageous embodiment provided that the recess by a circumferential, radially outwardly open groove is formed, the Groove is interrupted in the area of the openings. The groove can for example, in a setting in a lathe. Because the recess designed as a groove is rotationally symmetrical, the risk of imbalance in the finished support disc is further reduced.

The groove can have a substantially rectangular cross section and a depth which corresponds essentially to the height of the radial projection. The configuration of the support ring according to the invention results in Injection molding of the support ring on the support ring also no problems if the groove - viewed in cross section - with an undercut, e.g. B. is dovetailed. The contour of the support ring is thereby perfectly enclosed in the injection molding process that independently the air from the flow front also in the area of the undercuts Tool can escape. Through a groove with, for example dovetail-shaped undercut is also in this area positive connection created and the durability of the support ring and Support ring on each other further improved.

The radial projection can have end faces axially on both sides, each with at least one circumferential, self-contained Ring groove, the ring grooves with congruently designed projections of the Support ring are engaged. The entire radially outside area of the The support ring is enclosed by the support ring. The fact that the support ring and the support ring is mechanically clawed together in the area of its end faces the connection between the two parts is particularly permanent,  even if, for example, due to thermal expansion of the components to be supported an axial force acts on the support ring.

The openings preferably connect the end ring grooves in axial direction with each other. The preferably rounded ones Transitions that limit the ring grooves are marked by such Design flows around almost laminar during the injection molding process; undesirable inclusion of air is therefore almost impossible.

The support ring can be a radially inwardly open, essentially U-shaped Have mige profile that engages around the radial projection like a clamp. Penetration of contaminants and / or moisture into the The joint between the hub ring and the support ring is provided by a such configuration reliably prevented, especially if in addition to the positive connection between the support ring and the support ring a binder system is used to further improve To ensure adhesion of the two rings to each other. Centrifugal Deformations of the support ring can thereby be effectively countered.

The support ring can be made of aluminum or plastic. The support ring consists preferably of polyurethane.

Two embodiments of a support ring according to the invention further illustrated below with the aid of the drawings. Show it:

Fig. 1 shows a first embodiment of a supporting disc, in which the polymeric material of the support ring was injected through a central flow front of the supporting ring,

Fig. 2, the first embodiment of a supporting disc, in which the polymeric material of the support ring was molded by lateral flow fronts on the supporting ring,

Fig. 3 and 4 a second embodiment, with - based on the Figure 1 and 2 -... A modified carrier ring, wherein in Fig 3 the central flow front in Figure 4, the lateral flow fronts are shown,

Fig. 5 is a perspective view of a support ring as a separate part, which has a plurality, adapted to the number of perforations recesses in the form of bores,

Fig. 6 is a perspective view of a support ring having a circumferentially extending recess in the form of a groove.

In Figs. 1 and 2, a first embodiment of a support disk of the invention is shown. The support disc is used to support a rotor of an open-end spinning machine and in this case comprises a support ring 1 made of aluminum. A support ring 3 made of polymeric material is arranged on the outer circumference 2 of the support ring 1 and is injection molded onto the support ring 1 by an injection molding process. The support ring 1 and the support ring 2 are positively connected to one another. The support ring 1 is provided with a radial projection 4 which extends in the circumferential direction and which in the axial direction has eight openings 5.1 , 5.2 , evenly distributed in the circumferential direction. . ., 5.8 is permeated. The openings 5.1 , 5.2,. . ., 5.8 are completely filled by the polymer material of the support ring 3 , which results in a mechanical claw of the support ring 1 and support ring 3 to one another. The radial projection 4 is provided on the outer circumferential side with a circumferentially circumferential, radially outwardly open recess 6 in the form of a groove 7 , the groove base 8 of which in the area of the openings 5.1 , 5.2 ,. . ., 5.8 is interrupted.

In this exemplary embodiment, the groove 7 is undercut and, viewed in cross section, has a smaller axial width on the outside than on the radial inside. The dovetail-shaped undercut also carries, like the polymeric material of the support ring 3 within the openings 5.1 , 5.2,. . ., 5.8 , to a very durable connection between the support ring 1 and the support ring 3 .

In Fig. 1, the central flow front of the polymeric material during injection molding is shown schematically by arrow 17 . The arrows 18 and 19 symbolize the air displaced by the polymer melt, which completely escapes from the injection mold. The radial projection 4 of the support ring 1 is completely enclosed by the polymeric material of the support ring 3 and without voids. The polymer melt is injected into the groove-shaped recess 6 in the direction 17 and passes through the recess 6 into the openings 5.1 , 5.2,. . ., 5.8 , wherein the air displaced by the polymer melt also through the openings 5.1 , 5.2,. . ., 5.8 escapes from the injection mold.

In contrast, the lateral flow fronts are shown in FIG. 2, the injection of the polymer melt being symbolically represented by the arrows 20 , 21 , the polymer melt initially showing the openings 5.1 , 5.2,. . ., 5.8 flows through both end faces and the air to be displaced escapes through the recess 6 from the injection mold.

In FIGS. 3 and 4 is a second exemplary embodiment shown, in Fig. 3 corresponding to FIG. 1, the central flow front, in Fig. 4 other hand, the lateral flow fronts corresponding to FIG. 2 are shown. The arrows in FIG. 3 are as in FIG. 1, the arrows in FIG. 4 as in FIG. 2. In the second exemplary embodiment, the radial projection 4 is made wider than in the first exemplary embodiment, with circumferential, self-contained annular grooves 13 , 14 being screwed into the end faces 11 , 12 . The projections 15 , 16 of the support ring 3 are congruent to the ring grooves 13 , 14 and engage with them. Such a configuration results in the region of the radial projection 4, an essentially double-T-shaped cross section, the support ring 3 having a radially inwardly open, substantially U-shaped profile, which engages around the radial projection 4 like a clamp.

In each of the two exemplary embodiments it is the case that the recess 6 has a depth 9 which corresponds essentially to the height 10 of the radial projection 4 .

In Fig. 5 a perspective view of the support ring 1 is shown having a plurality of having the number of apertures 5 adapted recesses 6, in which the recesses 6 are each formed as holes. Such a support ring 1 can alternatively be used in the exemplary embodiments according to FIGS. 1 to 4.

In FIG. 6, a further embodiment of a supporting ring 1 is shown in which the recess is formed as a groove 6 and 7 circumferentially extends around the support ring 1, as in the embodiments according to FIGS. 1 to 4.

The design of the support ring 1 results in an excellent producibility of the support disk with good filling and venting behavior in the injection molding process. Blowholes in the elastomeric material of the support ring 3 are almost impossible, and the reject in the production of the support disks is therefore kept to a minimum.

Claims (8)

1. Support disc for the storage of a rotor of an open-end spinning machine, comprising a support ring and a support ring fixed on its outer circumference made of polymeric material, the support ring and the support ring being positively connected to one another, the outer circumference of the support ring having at least one radial projection Is penetrated in the axial direction by at least one opening and the opening is completely filled with the polymeric material of the support ring, characterized in that the radial projection ( 4 ) is provided on the outer circumference with at least one recess ( 6 ) which extends into the opening ( 5 ). extends. 2. A supporting disc according to claim 1, characterized in that the radial projection (4) is permeated evenly distributed in the circumferential direction in immoderately openings (5.1, 5.2...). 3. A supporting disc according to one of claims 1 or 2, characterized in that each one is opening into each opening (5.1, 5.2...) In substantially radially inwardly extending recess (6.1, 6.2...). 4. Support disk according to one of claims 1 or 2, characterized in that the recess ( 6 ) is formed by a circumferential circumferential, radially outwardly open groove ( 7 ), the groove base ( 8 ) in the region of the openings ( 5.1 , 5.2 . . ) is interrupted. 5. Support disc according to claim 4, characterized in that the groove ( 7 ) has a substantially rectangular cross section and a depth ( 9 ) which corresponds essentially to the height ( 10 ) of the radial projection ( 4 ). 6. Support disc according to one of claims 1 to 5, characterized in that the radial projection ( 4 ) has axially on both sides end faces ( 11 , 12 ), each with at least one circumferential, self-contained annular groove ( 13 , 14 ) and that Ring grooves ( 13 , 14 ) with congruently shaped projections ( 15 , 16 ) of the support ring ( 3 ) are engaged. 7. A supporting disc according to one of claims 1 to 6, characterized in that (.. 5.1, 5.2.) The perforations, the end-face annular grooves (13, 14) in the axial direction together. 8. Support disk according to one of claims 1 to 7, characterized in that the support ring ( 3 ) has a radially inward open, substantially U-shaped profile which engages around the radial projection ( 4 ) like a clamp.