CS214535B1 - Spinning facility for spindlelles spinning - Google Patents

Abstract

The invention relates to a spinning device open-end spinning including spinning the rotor and its drive train. The essence of the invention is that of the spinning at least one of its rotor the groove is separated from the drive train including storage as heat source energy, thermal insulation. The thermal insulation is air gap between outer and inner part of the spinning rotor or is formed an insert of flexible material which w V fills at least partially the air gap, or is formed between the spinning j rotor and its shaft. Heat insulation it is formed by a flexible body for the balance rotating mass. This body is a silenblock made of dynamic rubber. The invention is particularly useful in spinning rotors for open-end spinning working at high speed, k avoiding overheating of the spinning groove the rotor and reduce bearing wear as a result of the unbalance of the rotating mass.

Description

The present invention is a spinning device comprising a spinning device spins ^a 'eye rotor and its drive system.

. '·. ·· _? and

Recent developments in open-end spinning technology and technology allow new progressive spinning rotor solutions for open-end spinning machines, especially for high speeds, which nowadays range from 60,000 to 100,000 rpm.

One of the developmentally significant solutions of the spinning rotor and its bearing is the design according to DOS 2 433 712. In this case, a spinning rotor in the form of a plate is used, which is rotatably mounted directly in the twisting device with its outer surface.

This solution has a number of advantages such as simplicity of construction, economic power consumption and more. However, at higher speeds, problems are encountered, especially when spinning chemical materials, where the temperature of the collecting surface of the spinning rotor is high due to mechanical drive losses and bearings. However, the cooling of this spinning rotor is very imperfect. This is because the spinning rotor and the drive unit form a very compact whole and the heat enters the spinning rotor immediately from its origin.

The prior art methods of cooling the spinning bodies, either by providing fins on the body and thereby increasing the cooling surface, as well as providing a double-walled spinning body between the high-vapor-grade high-volatile chemicals where it condenses and sinks back into the original room with a higher temperature, they are insufficient at low speeds, low efficiency, and hardly proven to work in practice. . ^r

With increasing speed, this overheating of the spinning rotors of the open-end spinning machines also occurs with standard bearings and drive transmission from an endless belt or high-frequency motor, and this problem is solved by energy-intensive additional cooling, such as air-cooled air.

One such known solution is the method of cooling the spinning units of A, 0, 187 697, which relates to the cooling of the spinning units on an open-end spinning machine in which each spinning rotor is individually driven by a high speed motor. wherein the cooling air flow is separated from the process air so that cooling air is thrown into the interior of the spinning unit body against this charge, i.e. into the space between the spinning rotor and the motor rotor. From this space it moves away from the spinning rotor by two streams, one of which bypasses the motor rotor in the space between the rotor and the stator and the other bypasses the stator housing and is discharged from the housing behind the motor.

<. The device is designed so that a nozzle or a set of nozzles connected to a supply of cooling air flows through the wall of the body and opens into the body towards the hub in the spaces between the spinning rotor and the motor connected at least by a gap between the rotor and stator. cooling air formed in the body lid and the spinning unit. Said inner space of the body of the spinning unit is connected to the outlet openings also by means of bypass channels formed in the body wall around the stator housing.

The disadvantage of this device is that it is complex, energy intensive, since it requires each spinning unit to be provided with by-pass channels, it is necessary to install an air supply with nozzles. It is also necessary to install an air distribution system and a device for blowing air into individual spinning units. The machine becomes complicated, expensive and cooling air does not directly cool the spinning rotor body, but only the inner part of the spinning unit provided with the bearing and drive part.

Thereby, some of the heat is transferred to the spinning rotor and is heated. And, when heat is generated in the spinning rotor by friction of the fiber ribbon, the thermal gradient is then increased, the spinning rotor is overheated and the process air supplied is not sufficient to cool to a bearing limit.

The task is to substantially reduce the supply of thermal energy from the drive train and the placement into the collecting shaft of the spinning rotor. This object is solved by the present invention for an open-end spinning device comprising a spinning rotor and a drive thereof, wherein the spinning rotor has at least a region of its collecting groove separated from the spinning rotor, including the bearing, as a source of thermal energy, insulation.

Another feature of the present invention is that the thermal insulation is formed by an air gap provided between the outer and inner parts of the spinning rotor.

It is also an advantageous feature of the invention that the thermal insulation is formed by an insert of resilient material which fills at least partially the air gap provided between the outer part and the inner part of the spinning rotor.

Another feature of the invention is that thermal insulation is provided between the spinning rotor and its shaft.

A further advantage of the present invention is that the thermal insulation is formed by a flexible body for evacuating the rotating mass. A further feature is that the elastic body is formed by a dynamic rubber silenblock.

An exemplary embodiment, which naturally does not exhaust all possible variants, is shown in the attached drawing.

Figure 1 shows an axial section of the spinning device with a spinning rotor β outer and inner part, with thermal insulation formed by an insert over the entire gap between the two parts.

Figure 2 shows a spinning device with a thermal insulation formed by an insert that only partially fills the gap between the two parts of the spinning rotor.

Figure 3 shows a spinning device with an air gap heat insulation provided between the two parts of the spinning rotor.

Figure 4 shows a spinning device with thermal insulation provided between the spinning rotor and its shaft formed by a resilient body for rotating mass balance.

From these basic embodiments of the spinning device, other possible exemplary embodiments can be combined with various constructional modifications.

An advantage of the embodiment of the spinning device according to the invention is that the heat energy passing from the space of the spinning rotor to the collecting groove of the spinning rotor is braked in the space of the thermal insulation formed and does not go directly to the collecting groove. As a result, the collecting groove does not overheat and damage the fibers in the ribbon located on the collecting groove. The heating of the collecting groove due to the friction of the fibers can be sufficiently reduced by the supply of cold so-called process air. This cools the inner part of the spinning rotor and the process air is discharged in a known manner outside the spinning unit.

The spinning device 1 comprises a drive unit 6 mounted in its standing part and a rotatably mounted spinning rotor 2. The spinning rotor 3 is formed from an inner part 6 and an outer part 5. or is deposited on another known prinoip, for example magnetic, aerodynamic, aerostatic, sliding and the like. These mounting principles maintain the play 8 between the spinning rotor 2 ^{and the} drive housing 2. The drive mechanism 2 is firmly connected to the spinning rotor 2 by its one movable part, for example permanent magnets 10 (Figs. (Fig. 3). The motor windings 13 are part of the standing part of the spinning device 1 and in a known manner mediate the rotational movement of the spinning rotor 2 (FIG. 4).

A spinning groove 14 is provided between the inner portion 4 and the outer portion 2 of the spinning rotor. a spinning rotor 2 (see FIG. 1); However, it is possible to form the liner 16 so that it only partially fills the air gap 17 between the inner part 6 and the outer part 2 of the spinning rotor 2 ^and thus forms thermal insulation 15 (see FIG. 2). The liner 16 is made of a thermally insulating material with high internal attenuation properties such as bakelite, textile, vulcolang, foam rubber, silicone rubber and pdd.

It is also possible to form a spinning device 1 with a spinning rotor 2 made of an inner part 6 and an outer part 2, the thermal insulation 15 being formed by an air gap 12 which is formed between the inner part 6 and the outer part 2 of the spinning rotor 2.

It is also possible to provide the spinning device so that the inner part 6 of the spinning rotor 2 is made of a material with increased thermal resistance to the outer part 2. It can be made, for example, of eclolaminate, bakelite or stainless steel. If non-metallic materials are used to increase wear resistance and to remove static electricity, it is expedient to provide the inner portion 6 of the spinning rotor 2 with a protective coating 18 of metallic or other abrasion-resistant material, for example by vacuum vapor deposition. This further increases the effect of the thermal insulation 15.

Another embodiment of the spinning device 1 (FIG. 4) consists of a drive unit 2, an electric motor with a winding 12 driving a shaft 12 directly, which forms the motor armature and which is mounted on the bearings 6. The outer part 5 of the spinning rotor 2 is attached to the shaft 19 by means of a flexible body 20 which forms the thermal insulation 15. The spinning rotor 2 has an inner part 6 provided with a collecting groove 14. The elastic body 20 is constructed as a silenblock and has an effect on the balance of the rotating mass.

The device according to the invention operates as follows:

In a known manner, a strand of fibers is fed to a feed device of the opener device where the filaments are grasped by the tips of the combing roller and straightened and unified, after which the filaments are guided to the collecting groove 14 of the spinning rotor 2. The ribbon is twisted in the yarn and the prepared yarn is discharged through the discharge tube through the break-off sensor by the draw-off device and wound on the winding elements on a spool.

The thermal energy generated by the drive and bearing of the spinning device 1 passes through the thermal insulation 15 to the collecting groove 14 of the spinning rotor 2, compared to the heat transfer to the other non-insulated parts of the strc, very slowly and air, the collecting groove 14 of the spinning rotor 2 remains only slightly warmer than the temperature of the incoming process air from the ambient atmosphere during the spinning process, making it possible to spin without difficulty for all thermally sensitive chemicals without the need for any specially designed cooling equipment.

If the thermal insulation 15 is at the same time formed by the insert 16, the transfer of the imbalance from the collecting groove 14 to the bearings 6 (which imbalance arises from spinning due to impurities contained in the present textile material by uneven settling on the collecting groove 14 of the spinning rotor 2) ^; The spinning rotor 2 can also be cleaned and the service life of the rotating parts can also be extended.

These advantages furthermore have a very positive effect on the spinning economy, the quality of the spun yarn, reduce the energy requirements for cooling the spinning device 1, which also lowers the overall cost of building spinning machines with high revolutions of spinning rotors 3.

Claims (6)

SUBJECT OF THE INVENTION An open-end spinning device, comprising a spinning rotor and a drive thereof, characterized in that, from the spinning rotor (3), at least the region of the collecting groove (14) is separated from the drive device (9) as a heat source by thermal insulation (15). Spinning device according to claim 1, characterized in that the thermal insulation (15) is formed on an air gap (17) provided between the outer part (5) and the inner part (4) of the spinning rotor (3). Spinning device according to claim 1, characterized in that the thermal insulation (15) forms on the liner (16) a resilient material which fills at least partially the air gap (17) provided between the outer part (5) and the inner part (4) the spinning motor (3). 4. The spinning device according to claim 1, characterized in that the thermal insulation (15) is provided between the spinning rotor (3) and its shaft (19). Spinning device according to claim 4, characterized in that the thermal insulation (15) is formed by a resilient body (20) for balancing a rotating mass. Spinning device according to claim 5, characterized in that the elastic body (20) is formed by a dynamo-rubber silo block.