CZ294707B6 - Rotor spinning machine spinning apparatus - Google Patents

Abstract

The present invention relates to a rotor-spinning machine spinning apparatus (4) comprising a spinning rotor (41) formed by a double-side open body having the form of a ring with an inlet opening (412) and an outlet opening (414). The spinning rotor (41) is rotatably mounted within an air chamber (43) connected with a vacuum source and a stator (42) of a synchronous electric machine is assigned to said rotor (41). Said synchronous electric machine stator (42) is provided with at least two electromagnetic coils (421). The spinning rotor (41) consists of at least a spinning rotor (41) body that is intended to perform spinning function and that forms a load-bearing section of at least one permanent magnet (410) that is intended to perform the function of an electric rotor.

Description

Spinning mechanism of rotor spinning machine

Technical field

BACKGROUND OF THE INVENTION The invention relates to a spinning device of a rotor spinning machine comprising a spinning rotor formed by a double-open ring-shaped body with an inlet opening and an outlet opening, the spinning rotor being rotatably mounted in an air chamber coupled to a vacuum source. at least two electromagnetic coils.

BACKGROUND OF THE INVENTION

A solution according to CZ patent 284 734 (WO 99/11848) is known which relates to a spinning device of a rotor spinning machine comprising a reversibly open spinning rotor, which is formed by a ring of magnetically hard material and which is rotatably mounted in an air chamber. The inner wall of the spinning rotor defines the inlet opening of the spinning rotor and the outlet opening of the spinning rotor, and in the space behind the outlet opening of the spinning rotor, the air chamber is connected to a vacuum source. The spinning device of the rotor spinning machine is provided with a yarn draw-off funnel. The spinning rotor is magnetized perpendicularly to a plane passing through the axis of the spinning rotor, and a stator is provided around the outer peripheral surface of the spinning rotor, comprising at least two electromagnetic coils which form part of the stator housing of the synchronous electric machine. the solenoid coils of the stator are coupled to the frequency converter of the integrated spinning control system. At least three magnetic field sensors, which can be mounted in the stator between the pole pieces of the electromagnetic coils, are connected evenly around the outer periphery of the spinning rotor and are connected to the information inputs of the control circuit of the integrated control system of the spinning device.

A disadvantage of this solution is the difficulties encountered in forming a spinning rotor with defined magnetization. Another disadvantage of this solution is the magnetic aging of the spinning rotor, which significantly adversely affects the parameters of the spinning process with all negative consequences on the quality of the produced yarn.

SUMMARY OF THE INVENTION

The aforementioned disadvantages of the prior art are eliminated or reduced by the spinning device of the rotor spinning machine according to the invention, characterized in that the spinning rotor is composed of at least a spinning rotor body which is intended for the spinning function and forms a support part of at least one permanent magnet. which is designed for electric rotor function.

The advantage of this solution is the simplicity of achieving the defined magnetic properties of the spinning rotor, the time stability of these properties and at the same time a very favorable price of the spinning rotor.

From the viewpoint of simplicity of solution, it is advantageous if the spinning rotor body is provided with at least one permanent magnet in its interior space.

From the viewpoint of simplicity and efficiency of the spinning rotor, it is advantageous if the spinning rotor body is provided with a ring ring at its rear and / or front end.

- 1 CZ 294707 B6

In order to ensure the strength of the permanent magnet while providing sufficient space within the spinning rotor, it is advantageous if the permanent magnet is mounted at the front and / or rear end of the spinning rotor body in an auxiliary neck formed on the spinning rotor body.

From the viewpoint of manufacturing the spinning rotor, it is advantageous if the auxiliary neck is in the form of a cylinder shell and the permanent magnet is, with its outer peripheral surface, mounted on the inner peripheral surface of the auxiliary neck.

It is advantageous if the permanent magnet is connected to the spinning rotor body by gluing or soldering, since both gluing and soldering are reliable and at the same time relatively simple and technologically mastered methods of joining components.

In order to minimize the outer dimensions of the spinning rotor while maintaining the dimensions of the inner space and the functionality of the spinning rotor, the spinning rotor body is provided with a groove in which a permanent magnet is mounted.

In this embodiment of the spinning rotor, in accordance with one preferred embodiment, the groove for receiving the permanent magnet in the spinning rotor body is formed in the spinning rotor housing wall between the outer peripheral wall of the spinning rotor body and the inner wall of the spinning rotor.

According to another embodiment, the groove for receiving the permanent magnet in the spinning rotor body is formed in the inner wall of the spinning rotor.

From the aspect of outer dimensions and functionality, it is also advantageous to provide a spinning rotor according to which the spinning rotor housing has at least a portion of the length of the inner wall from the front end of the spinning rotor body to the rear end of the spinning rotor.

In this embodiment of the spinning rotor, in view of the stability of the spinning rotor and the achievement of the required drive parameters of the spinning rotor, it is advantageous if the permanent magnetic material layer is formed over the entire surface of the inner wall of the spinning rotor.

In order to prevent damage to the permanent magnet located directly in the cavity of the spinning rotor body on the inner wall by the movement of the unified fibers, it is advantageous if the permanent magnet is provided with a protective coating on its outer surface.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is schematically shown in the drawing, wherein FIG. 1 shows the arrangement of the working station of the rotor spinning machine, FIG. 2 shows a detail of the arrangement of an air chamber with a spinning rotor, FIG. 3 shows the arrangement of a spinning rotor with auxiliary neck at the front end of the spinning rotor; FIG. 5 shows the arrangement of the permanent magnet spinning rotor directly in the wall of the spinning rotor housing, FIG. 6 shows the arrangement of the permanent magnet spinning rotor in the inner wall of the spinning rotor housing, and FIG. 7 shows the arrangement of the permanent spinning rotor. a magnet over the entire surface of the inner wall of the spinning rotor body.

DETAILED DESCRIPTION OF THE INVENTION

The rotor spinning machine comprises a plurality of juxtaposed workstations, each of which serves separately for the production of yarn, and in operation each workstation is associated with one fiber sliver container 2.

-2 CZ 294707 B6

Each work station comprises a suitable fiber sliver feed device 1, into which an inlet portion comprising a fiber sliver feed roller 10 is guided by a fiber sliver 2 from a known container (not shown). The sliver feeding device 1 is driven either by the central drive of the rotor spinning machine with which it can be coupled by means of a clutch 11, see, Fig. 1, or is driven by an individual drive (not shown). The output part of the feeding device 1 is connected in a known manner by a suitable opener device 3, which comprises an opener roller 31, which in some known manner is coupled to a drive which is either the central drive of the rotor spinning machine, see Fig. 1 or driven by a not shown individual. drive. The output of the opener device 3 is formed by a suitable opener fiber feed channel 30 which opens into the spinning rotor 41 of the spinning device 4. The work station of the spinning machine further comprises a downstream drawing device 5 downstream of the spinning device 4 to draw the yarn 21 from the spinning rotor. A winding device 6 for winding yarn 21 onto the spool 61 is located downstream of the draw-off device 5. Between the spinning device 4 and the winding device 6 there is usually at least one pick-up device 7 for monitoring the quality and / or presence of yarn 21. In the illustrated embodiment, a yarn quality and presence sensor 71 is mounted between the spinning device 4 and the take-off device 5, and a yarn sensor 21 is positioned between the take-off device 5 and the winding device 6.

The spinning rotor 41 comprises a ring-shaped body of a suitable material, such as an aluminum alloy, steel, etc., which is open on both sides and is rotatably mounted in an air chamber 43 surrounding it airtight. As shown in the drawing, the spinning rotor body 41 includes a peripheral wall on its outer side and an inner wall 411 on its inner side which at its narrowest point at the front end of the spinning rotor body 41 defines an inlet opening 412 of the spinning rotor 41 into the transported fiber channel 30. From the inlet opening 412, the inner wall 411 towards the rear end of the spinning rotor 41 gradually extends to the collecting groove 413, and downstream of the collecting groove 413, the inner wall 411 narrows again at the rear end of the spinning rotor 41. through the opening 412 and the collecting groove 413, the inner wall 411 forms a sliding wall, over which the united fibers are conveyed from the conveying channel 30 to the collecting groove 413, where they are twisted in the yarn 2.

The spinning rotor 41 is comprised of at least two parts, one of which is formed by the spinning rotor body 41, which is intended to provide the spinning function, and which carries the other part of the spinning rotor 41, constituted by at least one permanent magnet 410 which is intended to provide the electric the rotor, i.e. the electrically directly driven spinning rotor 41.

In the exemplary embodiment shown in Figures 1 and 2, the spinning rotor body 41 is provided at its rear end with an auxiliary neck 416 having an inner diameter formed by the outlet aperture 414 of the spinning rotor 41. In the exemplary embodiment shown in Figure 3, the auxiliary neck 416 is situated on the front at the rear end of the body, the spinning rotor 41 terminates in an outlet opening 414 at the narrowest point of the inner wall 411. In the embodiment shown in FIG. 4, the auxiliary neck 416 is formed. at the front and rear ends of the spinning rotor body 41 and the inner diameter of the auxiliary neck 416 at the front end of the spinning rotor body 41 forms the inlet opening 412 of the spinning rotor 41 and the inner diameter of the auxiliary neck 416 at the rear end ru 41.

The auxiliary neck 416 has the shape of a cylinder housing in the illustrated embodiments (FIGS. 1 to 4). A discharge funnel 44 is provided in the outlet aperture 414 of the spinning rotor 41, whether or not it is an auxiliary neck 416, which is formed according to any of the many known embodiments. The diameter of the outlet aperture 414 of the spinning rotor 41 is greater than the maximum outer diameter

Of the discharge funnel 44, thereby allowing the process air to flow through the spinning rotor 41 from its inlet port 412 through its outlet port 414 from the spinning rotor 41.

In each auxiliary neck 416 on the spinning rotor 41 there is a permanent magnet 410, which is formed by a ring disposed by its outer peripheral surface on the inner peripheral surface of the auxiliary neck 416, and whose inner peripheral surface has the shape of a cylinder shell. In the embodiment shown in Figures 1, 2 and 4, in which the spinning rotor body 41 is provided with an auxiliary neck 416 at its rear end, the inner peripheral surface of the permanent magnet 410 forms an outlet 414 of the spinning rotor 41, is greater than the maximum outer diameter of the takeout funnel 44, thereby allowing process air to flow through the spinning rotor 41 from its inlet port 412 through its outlet port 414 away from the spinning rotor 41.

In the spinning rotors 41 according to the exemplary embodiments shown in Figures 1 to 4, the permanent magnet 410 is fixed to the spinning rotor body 41 in a suitable manner, e.g. by gluing or other suitable bonding method, and does not interfere with the yarn 21 formed by the take-off device 5. The permanent magnet 410 does not interfere with the path of the drawn yarn 21, for example, so that the front wall 4100 of the permanent magnet 410 situated in the auxiliary neck 416 at the rear end of the spinning rotor body 41 is in the direction of from the front end of the spinning rotor body 41 to the rear end of the spinning rotor body 41 situated at or beyond the front wall of the withdrawal funnel 44 as shown in Figs. 1 and 2.

As can be seen from the embodiment shown in FIGS. 5 and 6, the spinning rotor housing 41 may be provided with a permanent magnet 410 in a manner different from the previous embodiments, for example by providing a suitable groove in the spinning rotor housing. eg in the front wall of the spinning rotor body 41 between the outer peripheral wall of the spinning rotor body 41 (see Fig. 5) and / or directly in the inner wall 411 (see Fig. 6), and the groove thus formed is filled with suitable permanent magnetic material whereby a permanent magnet 410 is formed directly in the body of the spinning rotor 41. If the permanent magnet groove 410 is formed directly in the inner wall 411 (see FIG. 6), the permanent magnet 410 thus formed can be provided with a protective coating to increase wear resistance. Since many of the materials that are currently being made permanent magnets already have high wear resistance per se, the use of protective coatings is not necessary in all cases. It will be appreciated that a variety of equivalent arrangements of the permanent magnet 410 or even several permanent magnets 410 on one spinning rotor body 41 may be provided, e.g., the permanent magnet 410 may be formed in a groove located directly in the collecting groove 413 of the spinning rotor 41 etc.

In the embodiment shown in FIG. 7, the spinning rotor 41 is provided with a permanent magnet 410 such that the spinning rotor body 41 is provided on the inner wall 411 of the spinning rotor 41 with a layer of suitable permanent magnetic material which together form the permanent magnet 410. the permanent magnet 410 thus formed may be provided with a protective coating to increase its wear resistance, but, as mentioned above, the properties of many of the presently used permanent magnet materials can also be applied in view of their high wear resistance. In this arrangement, it is clear that the permanent magnet layer 410 can be formed only over a portion of the length of the inner wall 411 between the inlet port 412 and the outlet port 414 of the spinning rotor body 41.

In the embodiment (not shown), the spinning rotor 41 is provided with a permanent magnet 410 by another suitable method or other suitable means of construction.

The interior of the air chamber 43 is connected downstream of the outlet aperture 414 of the spinning rotor 41 by a vacuum line 415 to a source of vacuum, for example a source not shown below

Of the rotor spinning machine. For this reason, process air enters the spinning rotor 41 through its inlet orifice 412 and discharged fibers, and exits from the spinning rotor 41 through its orifice 414, passing through an annular orifice between the spinning orifice outlet 414 and the outer periphery of the take-off funnel 44. of the air chamber 43 directed towards the source of vacuum. This also cools the spinning rotor 41 and the permanent magnet 410 from the inside of the spinning rotor 41.

The permanent magnet 410 formed in the spinning rotor 41 forms a rotor of a synchronous electric machine, whose stator 42 is arranged outside the spinning rotor 41 around the periphery of the spinning rotor 41, e.g., as shown in Figs. an auxiliary neck 416 at the rear end of the spinning rotor body 41.

The stator 42 of the synchronous electric machine forms part of the walls of the air chamber 43 in which the spinning rotor 41 is housed, the gap formed in the operating state between the spinning rotor 41 and the air chamber 43 both prevents the spinning rotor 41 and the air chamber 43 from touching each other. flowing a small portion of the process air around the outer periphery of the spinning rotor 41, thereby simultaneously cooling the spinning rotor 41 from its outside and the air chamber 43 including the stator 42 of the synchronous electric machine. At the same time, this flow removes dust particles and fibers from the space around the outer periphery of the spinning rotor 41. The above-mentioned operating state is understood to mean that the permanent magnet 410 is subjected to both magnetic field components from at least two electromagnetic coils 421. a magnetic field with an axial force component that lifts the permanent magnet 410 of the spinning rotor 41 and thereby the entire spinning rotor 41 into and maintains the operating position, and a magnetic field with a rotational force component that rotates the permanent magnet 410 and with it the entire spinning rotor the rotor 41 in a predetermined direction at a predetermined speed and keeps it rotating.

In order to minimize the possibility of damage to the spinning rotor 41 and the air chamber 43 including the stator 42, the spinning rotor 41 may be provided with a protective coating on its outer periphery and / or the inner surface of the air chamber 43 including the stator 42, in particular on the parts surrounding the spinning rotor 41. eg plastic or rubber.

Other connections of the individual parts of the spinning device 4 to the other parts of the rotor spinning machine workstation and to the parts of the whole rotor spinning machine, eg the particular arrangement of the stator 42 of the synchronous electric machine and the spinning rotor 41, the arrangement and connection of the stator 42 as such. 421 of the stator 42, the connection of the spinning device 4 and its individual parts to the integrated control system of the spinning device 4, the arrangement and function of the integrated control system of the spinning device 4 including its power supply and links to individual systems or parts of the systems of the rotor spinning machine. stabilization of the spinning rotor 41 or use of stabilization of the spinning rotor 41 by means of an autostabilizing function of the magnetic field, mutual arrangement of individual parts and elements of the spinning device 4, operation of the spinning device 4 and related other parts and nodes of the rotor spinning machine during start-up, running and stopping of the spinning rotor 41 as well as during renewing spinning and cleaning of the spinning rotor 41; the spinning rotor 41, the operation of the entire system in the event of a power failure, etc., are feasible for any person skilled in the art based on his or her expertise and skills. A suitable embodiment of the above arrangements, linkages and activities is also detailed in CZ patent 284 734 (WO 99/11848) and can be appropriately used or appropriately modified for the device according to the present invention.

Claims (5)

A spinning device of a rotor spinning machine comprising a spinning rotor comprising a double-open ring-shaped body with an inlet opening and an outlet opening, the spinning rotor being rotatably mounted in an air chamber coupled to a vacuum source and assigned a stator of a synchronous electric machine comprising at least two electromagnetic A coil, characterized in that the spinning rotor (41) is composed of at least a body which is intended for the spinning function and forms a support part of at least one permanent magnet (410) which is intended for the electric rotor function. Spinning device according to claim 1, characterized in that the body of the spinning rotor (41) is provided in its internal space by at least one permanent magnet (410). Spinning device according to claim 2, characterized in that the body of the spinning rotor (41) is provided at its rear and / or front end with a permanent magnet (410) formed by a ring. A spinning device according to claim 3, characterized in that the permanent magnet (410) is mounted at the front and / or rear end of the spinning rotor body (41) in an auxiliary neck (416) which is formed. on the spinning rotor body (41). A spinning device according to claim 4, characterized in that the auxiliary neck (416) has the shape of a cylinder shell and the permanent magnet (410) is mounted on the inner peripheral surface of the auxiliary neck (416) by its outer peripheral surface. Spinning device according to any one of claims 1 to 5, characterized in that the permanent magnet (410) is bonded to the spinning rotor body (41). Spinning device according to any one of claims 1 to 5, characterized in that the permanent magnet (410) is connected to the spinning rotor body (41) by soldering. Spinning device according to any one of claims 1 and 2, characterized in that the body of the spinning rotor (41) is provided with a groove in which the permanent magnet (410) is received. Spinning device according to claim 8, characterized in that the groove for receiving the permanent magnet (410) in the spinning rotor housing (41) is formed in a wall of the spinning rotor housing (41) between the outer peripheral wall the spinning rotor body (41) and the inner wall (411) of the spinning rotor (41). A spinning device according to claim 8, characterized in that the groove for receiving the permanent magnet (410) in the body of the spinning rotor (41) is formed in the inner wall (411) of the spinning rotor (41). Spinning device according to any one of claims 1 and 2, characterized in that the spinning rotor body (41) is at least part of the length of the inner wall (411) from the front end of the spinning rotor body (41) to the rear end of the spinning rotor body (41). ) provided on the periphery of the spinning body (41) with a permanent magnet (410) formed by a layer of permanent magnetic material. -6GB 294707 B6 Spinning device according to claim 11, characterized in that a layer of permanent magnetic material is formed over the entire surface of the inner wall (411) of the spinning rotor (41). A spinning device according to any one of claims 10 to 12, characterized in that the permanent magnet (410) is provided with a protective coating on its outer surface.