CS221539B2 - Locating the rotor of the spindleless spinning machine firmly connected to the shaft - Google Patents

Abstract

A mounting assembly for an open-end spinning machine rotor 1 includes three frusto-conical rollers 4, 5 supported by a housing 9 with their axes passing through the apices of an equilateral triangle and meeting at a point on the axis of a shaft 2 carrying the rotor 1. The rotor 4 is driven by an electric motor 11 and a shaft 10. The rotor shaft 2 has a frusto conical surface 3 which is held, by the action of magnets 16, in contact with the frusto conical surfaces of the rollers 4, 5. The drive may be by friction belt. <IMAGE>

Description

The invention relates to a rotor housing of an open-end spinning machine fixedly coupled to a shaft in a housing, wherein the rotor shaft is located between three support rollers.

It is associated with considerable difficulties if the rotor bearings are to be designed in such a way that, on the one hand, fault-free operation is ensured for a longer period of time and, on the other hand, the high-speed noise generation is kept within tolerable limits. An aggravating circumstance is furthermore that rotors, which are now horizontal, must be freely accessible from one side both for spinning techniques and for easy replacement, so that only a one-sided bearing can be considered.

So that high speed can be reliably absorbed at the smallest possible friction in the bearing, the bearings have used today form the embodiment so that the rotor shaft is radially partly held in the nip, which is formed by two opposing double ^and CEM ^I of ^Walking myc ^h roller bea ^ ^d on ^{and the} holding part holds Ruhe tangential drive belt engaging the shaft, the shaft .This nip. This embodiment is described in DOS 2,047,569 and corresponding British Pat. No. 1,324,734.

^From the VLA proMemattekým ^T is ^straight and that of ^P · ůsotou uložern, axial ^p from ^{p d} ren and held ^and the rotor, since the rotor must be ZA2 despite the SNA ^Copper exchangeability ^of the ^KP EVN held in the receptacle,. To. reliably prevent it from being ejected.

It is already known to use at least two thrust bearings in order to overcome the difficulties encountered in mechanical axial devices. magnets, which in the axial direction of the shaft are spaced apart from one another by the same poles, one of which is connected to the shaft or to the rotor of an open-end spinning machine, and the other is arranged immovably. Although this arrangement guarantees both axial locking and easy replaceability of the rotor, it has shown. It is disadvantageous that, due to external influences, the rotor tends to vibrate or to wobble, resulting in axial deviations of the rotor which interfere with the spinning process. Since the shaft bears two points on the support rollers at an axial distance, there are also lever forces which, due to the friction resulting therefrom not only lead to considerable noise generation, but also involve difficulties in accelerating or maintaining rotation.

In another known embodiment described in DOS 2 012 490 and the corresponding art. U.S. Pat. Pat. No. 144,431 which relates to a drive and holding zařízern · ^P ro spMtam rotors; where the rotor shaft is provided with radial. The problems of axial stabilization of the rotor are to be eliminated by the fact that the magnets are aligned with the axial distance with the surfaces substantially oriented radially and containing magnetic pairs of the same name, at least two pairs of surfaces being arranged in such a way that the axial distance of the surfaces of these pairs changes with respect to the axial movement of the shaft. Such an arrangement is already costly in construction, since the narrowest tolerances must be maintained between the retaining ring and the housing in order to allow easy dismantling and to prevent the rotor from ejecting. However, once the bearing is secured with the screws, the rotor replacement becomes tedious and inconvenient.

In addition, a twist-twisting spindle is known with a stationary spool carrier removable from a spindle rotor, in which three support rollers are provided, which are located in the corners of an equilateral triangle and which hold a hollow axis therebetween. or a hollow spindle. In this case, however, it is a bearing of a vertically standing spindle in which, due to the weight of the coil support, it is unnecessary to provide additional axial locking.

In view of this prior art, the present invention is based on the object of eliminating these disadvantages and of providing a support for an open-end spinning machine rotor fixedly coupled to the shaft shaft so that the above-mentioned requirements have been met in a simple manner. maintenance and to ensure that the rotor is not prone to failure.

According to the invention, the problem is solved by providing the rotor shaft with a tapered housing surface in a bearing which is formed by itters in the corners of an equilateral triangle with conical support rollers with axes extending obliquely to the axis of the shaft, the axes α-extended the surfaces of the conical surfaces of both the shaft and the support rollers intersect at a common point, and wherein one of the support rollers is connected to the drive member, and at least one magnet is mounted on the rotor and / or the housing to hold the shaft the rotor in contact with the support rollers.

The method of mounting the invention proposed has the advantage that the rotor shaft is considerably shorter than the known embodiments, so that, in connection with the three-point bearing, an accurate guide is obtained which prevents vibration or axial misalignment of the rotor with great reliability. In addition, such a bearing is characterized by smooth running and allows the rotor to be replaced quickly and without problems.

According to a preferred embodiment of the invention, one of the support rollers is mounted on a pin which is rigidly coupled to an electric motor.

However, it is also possible that one of the support rollers is driven by a friction roller. Such an embodiment is advantageous because the motor can be accelerated to the desired high speed in a short time without slip and can effortlessly keep it constant by direct drive. The axial oscillating movements of the shaft during braking and acceleration are reliably eliminated.

According to another embodiment of the invention, one of the support rollers is mounted on a pin which is driven by a tangential belt at its free end facing away from the support roller. Such an embodiment has the advantage that the bearing according to the invention is also suitable for a conventional tangential belt drive, and the disadvantages are avoided by the proposed bearing arrangement.

In a simple manner, according to a further embodiment of the invention, axial locking of the rotor is achieved by placing a magnet corresponding to the diameter of the shaft end directly in the housing directly against this end.

According to another embodiment of the invention, three rod magnets are provided on the housing between the support rollers, which cooperate with the rotor or with the annular metal disk connected to the rotor.

According to a further embodiment of the invention, the magnet is designed as an annular magnet and lies in the housing against the front face of the rotor which faces the shaft. As the experiments have shown, the proposed embodiments of the invention achieve a reliable support for the rotor, which is sufficient to maintain the rotor securely in position despite easy replaceability and to provide close contact between the shaft and the support rollers required for drive.

According to a further embodiment of the invention, said embodiment can also be designed such that the rotor is on the front side facing away from the shaft. - covered by - the housing parts, and - in this part of the housing as well as - in the rotor - axially extending bores for receiving bar magnets are provided, the same polarization.

Such a design is particularly advantageous since, in the event of any wear on the support rollers, the gap between the rotating and stationary components increases, so that the rotor can in no way abut the stationary components and thus block.

If in most cases it is sufficient to provide permanent magnets for the axial bearing of the rotor, it is not possible to use electromagnets instead of such magnets if necessary. ·

The invention will now be described in more detail with reference to the drawings.

Giant. 1 shows a longitudinal section of the rotor bearing according to line I-I in FIG. 2.

Giant. 2. shows a partial cross-section along the line TI-II in FIG. 1,

Giant. 3 shows schematically another embodiment of the invention, which is also shown in FIG. 4.

Giant. 5 schematically shows yet another embodiment of the invention.

In all embodiments, the rotor 1 is rigidly connected to the shaft 2, which has a conical ^casing surface ³ TOVO ^to Tero is held in a bearing which is formed by three conical bearing of ^{ky and} LEC ^{4, 5} -a ^{6 to E} ter in uimsteny corners of an equilateral triangle and have axes running obliquely to. shaft axis 2.

^{dl p} o r ^b e o. ¹ and ² are ^alkyl, support cylinder ⁵ and 6 are supported freely rotatably supported with interposition of ball .ložisek 7 on a pin 8 which is on one side rigidly connected to the housing 9 bezvřeitenového spinning machine. To support the rotor 1, the support roller 4 is mounted on a pin 10, which is fixedly coupled to an electric motor 11. The pin 10 is rotatably supported by ball bearings 12 in a sleeve 13, which is fitted in the bore 14 in a manner 9.

For axial -držení rotor 1 is attached ^{to the p} rstencový ovový Ota ^No. 1 ^{to 5 kt} projecting into the cavity interacts with the rod magnets 16 disposed between the support rollers 4, 5 and 6. Rod magnets 16 they are firmly anchored in -skříni 9 and cares 'that the shaft 2 of the rotor 1 continues to stay ^and the ^l st -v US carrier ^{yk and the} roller ^alkyl of 4, ⁵ and 6th

In the embodiment according to FIGS. 3 and 4, the rotor 1 is mounted in a conical bearing surface 3 of the shaft 2 in conical support rollers 5 ^{, 6} and ¹⁷ , which in this embodiment are generally freely rotatably supported on the pin 8. To drive the rotor 1, A tapered friction roller 18, which is fixedly connected to the electric motor 11 by means of a pin 19, is also attached to the support roller 17. To rotate the rotor 1 axially, an annular metal disc 15 is also mounted on this rotor. which is located in the housing 21 containing the rotor 1 so that it lies opposite the front side of the rotor 1, which faces the shaft 2.

The embodiment according to FIG. 4, which essentially corresponds to the embodiment shown in FIG. 3, differs only in that the axial holding of the rotor 1 is provided at the end of the shaft 2 with a metal disk 22 which cooperates with a magnet 23 of the same diameter. it lies directly against it in the bore 24 of the housing 9.

While in the above-described exemplary embodiments, the rotor is pulled into the bearings by means of magnets, FIG. In this bearing, whose construction essentially corresponds to that shown in FIG. 1, the rotor 25 on the side facing away from the shaft is covered by a housing part 26 which is pivotable around a pin 27 and secured against unintentional opening by the spring member 28. In this case, both ^the portion 26 of ^{an NE,} and ^to the rotor ²⁵ arranged in axially extending bores 29 and 39 for receiving -tyčových magnets 31 and 32. The bar magnets 31 and 32 located at both end surfaces 33 and 34 against each other on the common sub-ring, the faces of the rod magnets 31 and 32 facing each other have the same polarity and therefore press the rotor 25 into the bearing. *

Unlike přímého- driving the support roller 4, popsaného- in the embodiment of FIG. 1, there is shown in phantom, that the rotor 10 at its e ^j volrám ^{to ONC-d} facing the supporting roller 4, a belt driven -tangenciálním 35th

Claims (8)

Subject A rotor bearing of an open-end spinning machine fixedly coupled to a shaft in a housing, wherein the rotor shaft is located between three support rollers, characterized in that the rotor shaft (2) is a tapered housing surface (3) housed in a bearing. consisting of three conical support rollers (4, 5, 6, 17) arranged in the corners of an equilateral triangle, with axes running obliquely to the axis of the shaft (2), the axes and extended surfaces of the conical surfaces of both the shaft (2) and the supporting rollers (4, 5, 6, 17) intersect in a common ^{b of} _from: ^PR i ^No em ^{Ž d} en -of the carrier rollers ^{spark plug} (4, 17] is connected -s drive member (11, 18, ³⁵ h on the rotor ^(1, 25) no ^b a / a housing ^(9, 2ϋ) is disposed at least one magnet (16, 20, 23, 31, 32) which keeps the shaft (2) of the rotor (1, 25) in contact with bearing rollers (4, 5, 6, 17). Bearing arrangement according to Claim 1, characterized in that one of the support rollers (4) is fastened to a pin (10 ·) which is rigidly coupled. THE INVENTION of women with an electric motor (11). Bearing arrangement according to Claim 1, characterized in that one of the support rollers (17) is driven by a friction roller (18). 4. Storage according to item 1 _, characterized in that one of the support rollers (4) is at evněn -na ^{p p} u EN (Wh which is ^{- world} Free ^E m m co-nch inverse of ^d carrier for ^eh a roller (4), driven by a tangential belt (45). 5. Shaft according to any one of claims 1 to 4, characterized in that the magnet (23) as to ^p objpovídajím Rumer ^toward the downstream end. ⁽²²⁾ the shaft ^is in Wožen slknrn (9) Pumo tomuto- opposite end. 6. Save the ^P-dl e .toeréhoko HV ^{d b} of about 1 to 4, characterized in that between the supporting rollers (4, 5, 6] are -skříni (9) are arranged three tons ^YC oic magnets (Wh are exercised ^{to -} together ^Pooh reindeer -s rotor (1) or an annular metal disc (15) -S tímto- rotor (1) connected. A bearing according to any one of Claims 1 to 4, characterized in that the magnet is in the form of an annular magnet (20) and lies in the housing (12) against the front side of the rotor (1) facing the shaft (20). 2). A bearing according to any one of Claims 1 to 4, characterized in that the rotor (25) is covered on the end facing away from the shaft (2) by a housing part (26), both in the housing part (26) and in the housing (26). axially extending bores (29, 30) are provided in the rotor (25, 30) for receiving rod magnets (31, 32) which face each other on both faces (34, 3з) on a common sub-circle and have surfaces k The same poles face each other.