EP4025729A1 - Godet roll - Google Patents

Abstract

The invention relates to a godet roll, which comprises a godet roll drive motor, a motor mount, a rotatably mounted drive shaft that is driven or drivable by the godet roll drive motor and arranged centrally in the godet roll and oriented in the axial direction of the godet roll, wherein a rotor of the godet roll drive motor is fixed to a peripheral region of the drive shaft, a godet roll shell connected to the drive shaft, a godet roll shell heater enclosed by the godet roll shell and at least one cooler, wherein, according to the invention, at least one part of the godet roll drive motor, the motor mount and at least one fluid channel of the cooler are arranged in a portion of a region of the godet roll enclosed by the godet roll shell in which the godet roll shell heater is also arranged.

Description

Galette

The present invention relates to a godet, which has a godet drive motor, a motor bearing, a rotatably mounted drive shaft that is driven or drivable by the godet drive motor, is arranged in the center of the godet and aligned in the axial direction of the godet, a rotor of the godet drive motor being attached to a peripheral area of the drive shaft , a godet jacket connected to the drive shaft, a godet jacket heater enclosed by the godet jacket, and at least one cooling system.

A godet of this type is a driven, rotating roller for filament production used in the textile industry, especially in spinning mills. At least one thread, at least one fiber or at least one band is guided on the heated lateral surface of the godet. In practice, several godets, arranged in different levels and offset from one another and operated at different speeds, are usually combined to form a stretching roller unit. Typically, godet sleeves rotate at a peripheral speed of up to 5000 meters per minute.

The heating of the godet is essential for filament production. The cylindrical godet jacket is heated from the inside by the godet jacket heater, which is usually designed as an induction heater, whereby moisture can be brought out of the thread, fiber or strip guided on the godet jacket.

The temperature of the godet is typically recorded by means of at least one thermal sensor and transmitted to a godet control with the aid of a measured value transmitter.

The godet casing is set in rotation with the aid of the godet drive motor. For this purpose, it is customary in the prior art, as for example in the publication DE 10 2014 006 854 A1, to provide a hub at one end of the godet jacket, which is firmly connected to a shaft end of a drive shaft protruding from a bearing housing designed as an electric motor and is integrated with the drive shaft coupled to the bearing end of the godet drive motor. The high temperatures that are used in the godet heating are, however, a technical disadvantage for the godet drive motor, the bearing components of the godet and the measured value transmitter.

Due to the local separation of the godet drive motor from the hot godet jacket in the prior art, the godet drive motor, which runs warm even during operation, on the one hand does not get any hotter and on the other hand can be suitably cooled by means of a cooling device. The cooling devices for godet drive motors described in the documents EP 0 424 867 A1 and EP 0 454 618 B1 use cooling air. The air cooling can be assisted by an externally driven fan.

However, the use of coolant to cool the engine is also particularly advantageous. It is known to accommodate the godet drive motor and bearing components of the godet in a water-cooled housing arranged at a distance from the godet heater.

In the publication EP 1 126 061 A2, in which the godet drive motor is also provided remote from the godet heater, the bearing components of the godet, by which the drive shaft of the godet is rotatably supported, are cooled by means of a combination of air and steam cooling.

In the known godets, the measured value transmitter used in each case is also arranged away from the godet heater. It is typically air-cooled.

However, these constructions also result in disadvantages, such as a large overall length of the godet with a comparatively small effective area, which leads to a considerable space requirement, especially with set godets, as well as high mechanical loads and an associated premature wear of the bearing elements for the godet shell when the Galette jacket storage is arranged away from the godet heater.

Furthermore, if different temperature control systems are used to cool the individual components of the godet, several energy sources are required, which in turn leads to increased space requirements and increased maintenance and service costs.

It is therefore the object of the present invention to propose a godet which requires less space and is less subject to wear than the solutions known in the prior art.

This object is achieved by a godet which has a godet drive motor, a motor bearing, a rotatably mounted drive shaft that is driven or drivable by the godet drive motor, is located in the center of the godet and is aligned in the axial direction of the godet, a rotor of the godet drive motor being attached to a peripheral area of the drive shaft is, has a godet jacket connected to the drive shaft, a godet jacket heater enclosed by the godet jacket and at least one cooling system, at least part of the godet drive motor, the motor bearing and at least one fluid channel for cooling in a section of a region of the godet enclosed by the godet jacket, in which the godet jacket heating is also arranged, are arranged.

The entire godet drive motor is preferably arranged in the region of the godet which is cooled by the at least one fluid channel of the cooling system and is enclosed by the godet jacket and in which the godet jacket heater is also arranged.

The present invention thus turns away from the prior art, in which one has always tried to arrange the godet drive motor as far away as possible from the godet jacket heating in order to avoid additional heating of the godet drive motor, which is already very hot during operation, by the godet jacket heating. In contrast to the prior art, in the godet according to the invention at least a part of the godet drive motor, preferably the entire godet drive motor, is even arranged in a region of the godet heated by the godet jacket heating.

Thus, the godet drive motor is no longer - as in the prior art - provided at one end of the godet jacket surrounding the godet jacket heater. The inventive arrangement of the godet drive motor within the godet jacket and the godet jacket heater instead saves space. This saved Space can e.g. B. with a limited installation area for a total length reduction of the godet, but also with the same installation area for increasing the effective area of the godet.

In the godet according to the invention, the motor cooling is implemented by a fluid cooling system which has the at least one fluid channel and which runs between the godet drive motor and the godet jacket heater. The main effect of the fluid cooling is that the waste heat from the godet drive motor is dissipated, since it is arranged in the immediate spatial vicinity of this. A fluid channel or a plurality of fluid channels can be formed in the material of the carrier.

The fluid cooling also removes heat from the motor mounting and preferably from a measured value transmitter of the godet. In the present invention, it is a uniform temperature control system which extends over the godet drive motor, the motor mounting and preferably the measured value transmitter of the godet and is located in an area within the godet jacket and the godet jacket heating.

The godet according to the invention is designed in such a way that the mounting for the godet drive motor is also provided in the area of the godet enclosed by the godet jacket, ie in an area in which the load occurs on the godet. There is therefore no lever arm that increases the resulting force on this bearing. In the present invention, the motor mounting also serves as a godet jacket mounting.

In a preferred embodiment of the godet according to the invention, the at least one part of the godet drive motor and the at least one part of the motor mounting are arranged in an interior space of a carrier, the at least one fluid channel between the godet drive motor and the godet jacket heater running through the material of the carrier.

Since, according to the invention, the godet drive motor is located in an area of the godet in which the godet jacket heater is also located, in this embodiment of the invention, in which the godet drive motor is located in an interior of the carrier, the godet jacket heater is around at least a portion of the carrier arranged. This section of the carrier at least partially shields the godet drive motor from the thermal radiation of the godet jacket heating.

The carrier forms a stable receptacle for the fluid cooling and thus physically and thermally separates the godet drive motor from the godet jacket heating.

The at least one fluid channel can be integrated in the carrier in such a way that the fluid cooling extends at least so far over a length of the carrier that the same fluid cooling cools the godet drive motor, the motor and godet casing bearings, corresponding sealing components and a measured value transmitter of the godet.

The carrier does not rotate. Electrical connection lines to the godet drive motor can advantageously be routed into the interior of the carrier. The stator of the godet drive motor can be securely fastened inside the carrier. That is, the position of the godet drive motor can be fixed well. Furthermore, the carrier offers additional stabilization of the godet and protection of the godet drive motor and the motor mounting. This arrangement is also space-saving.

The carrier is preferably designed to be rotationally symmetrical. The godet drive motor and the motor mounting can then be accommodated well in the cylindrical interior of the carrier. The rotationally symmetrical shape of the carrier is adapted to the shape of the godet. However, in other embodiments of the present invention, the carrier can, for example, be plate-shaped or curved.

The carrier can be formed in one piece or from several layers and / or components.

In an advantageous embodiment of the present invention, the cooling has a coiled tube with a supply and a return for a cooling fluid arranged next to one another. Due to the helical design of the tube forming the at least one fluid channel, the cooling liquid can be guided around the entire circumference of the godet drive motor. The coiled tube forms a closed cooling circuit with connections for flow and return at a start and a deflection at one end of the coil. In the course of the coiling of the coiled Pipe, the flow is next to the return, so that even cooling is guaranteed.

It is also advantageous if the flow and return of the coiled tube are at the same distance from one another.

It has proven to be particularly advantageous if the flow and the return of the cooling are next to each other in the same cylindrical plane of the carrier and / or if the flow and the return of the cooling are next to each other in relatively graduated planes of the carrier and / or if the flow and return of the cooling lie on a conical surface plane of the carrier. That is, the flow lies directly next to the return on the same diameter and / or the flow and the return are on offset diameter steps and / or the flow and the return conically converge or diverge. This results in a particularly slim cooling system that is adapted to the other dimensions of the godet, so that the godet can be made compact overall.

The coiled tube is preferably a steel tube which is cast into the material of the carrier. The steel tube has a long service life and good thermal conductivity, so that advantageous cooling is provided permanently and almost maintenance-free.

In further developments of the godet according to the invention, at least one further coil, in which a medium other than the cooling fluid is guided, runs parallel to the coiled tube of the cooling system, in the material and / or on an inner wall of the carrier. With the help of the further helix, for example, lubricant can be conveyed to individual components of the godet, such as the bearings.

The carrier is preferably made of metallic and / or mineral material. A metal, such as. B. made of aluminum or cast iron, trained carrier has a particularly good thermal conductivity, whereby the temperature of the heated godet drive motor can be derived particularly effectively. Alternatively, the carrier can be formed from a plastic with good thermal conductivity. A mineral carrier material, on the other hand, can be used to achieve an at least partial thermal decoupling between the godet drive motor and the godet jacket heating by means of the carrier. In order to ensure good heat dissipation of the waste heat from the godet drive motor through the fluid cooling integrated in the carrier, it is advantageous in this embodiment if the fluid cooling is provided closer to the godet drive motor than to the godet jacket heater and / or at least to the godet drive motor facing side of the carrier, a good heat exchanger, such as a metal sleeve or metal coating, is provided.

The carrier is preferably designed in such a way that it has a carrier insert which is sunk into the region of the godet enclosed by the godet jacket, and a carrier attachment on which the godet jacket rests. In this way, the godet jacket with the godet jacket heating provided therein can advantageously be slipped onto the carrier insert and this construction can be placed on the carrier attachment.

The godet jacket heater can thus be placed on the carrier, the material of the carrier causing thermal decoupling, so that the cooling integrated in the carrier cools the godet jacket heater only slightly. Furthermore, with this construction, the godet jacket heating can be designed separately and electrically contacted and subsequently be suitably integrated into the godet, in particular into the space between the godet jacket and the carrier.

In addition or as an alternative to fluid cooling, air cooling can also be provided through at least one air channel formed in the material of the carrier and / or on an inner wall of the carrier.

In an advantageous embodiment of the invention, a distance in which there is air is set between the godet jacket heating and the carrier by at least one spacer. The spacer or spacers is / are preferably made of at least one poorly thermally conductive material. For example, two Teflon rings which are applied to the carrier at a distance from one another, for example pushed on, and on which the godet jacket heater rests, can serve as spacers. The air between the godet jacket heater and the carrier is a poor conductor of heat. This ensures that the carrier absorbs less heat from the godet jacket heating and can therefore better dissipate heat from the godet drive motor. In addition, more of the heat generated by the godet jacket heating can be given off to the godet jacket.

Additional cooling is achieved in a further embodiment of the invention in that a fan wheel, which rotates with the drive shaft, is placed on the drive shaft within the carrier. The fan impeller protects the godet drive motor and the bearing components of the godet from heat that arises due to heat conduction from the godet jacket via the drive shaft. The fan wheel is located below the carrier in which the fluid cooling is integrated. The rotation of the fan impeller creates air turbulence between the fluid cooling system and the drive shaft, so that the heat conduction via the drive shaft is reduced. The fan wheel can also sit under the fluid cooling.

One or more thermal sensors are preferably arranged in the interior of the godet, for example in the godet jacket. The connecting cables of the thermal sensors run at one end of the drive shaft in a measured value transmitter designed as a rotary transmitter, via which the measured temperature signals can be transmitted, for example, to an external control and / or evaluation unit of the godet.

In an expedient embodiment of the present invention, the measured value transmitter has a rotatable part which is attached to the drive shaft and a stationary part which is fastened in the carrier, with an air gap between the rotatable part and the stationary part of the measured value transmitter over which a signal is transmitted.

The invention is described in more detail below on the basis of exemplary embodiments and associated figures, without being restricted to these.

Show:

Figure 1 schematically shows a longitudinal section through an embodiment of a godet according to the invention; FIG. 2 schematically shows a perspective top view of a carrier of an embodiment of the godet according to the invention; and

FIG. 3 schematically shows a perspective view of a cooling coil of an embodiment of the godet according to the invention.

FIG. 1 is a sectional side view of an embodiment of a godet 1 according to the invention.

The godet 1 has in the center a drive shaft 5 aligned in the axial direction R of the godet 1. The drive shaft 5 is rotatably mounted.

The drive shaft 5 is driven by a godet drive motor 2 of the godet 1 or can be driven by this. For this purpose, a rotor 21 of the godet drive motor 2 is attached to a circumferential area of the drive shaft 5, in a course area of the drive shaft 5, that is not to the end thereof. Accordingly, the drive shaft 5 can be rotated with the rotor 21 and is well held in its position.

The godet drive motor 2 is mounted by means of a motor mounting 4 seated on the drive shaft 5.

In the embodiment shown, the motor mounting 4 has a first bearing 41 in front of the rotor 21 of the godet drive motor 2 and a second bearing 42 behind the rotor 21 of the godet drive motor 2 in the longitudinal alignment of the godet 1. The first bearing 41 and the second bearing 42 are each ball bearings in the embodiment shown. Both the rotor 21 of the godet drive motor 2 and the godet casing 7 with the drive shaft 5 are supported by the bearings 41, 42.

With the drive shaft 5, a godet jacket 7 of the godet 1 is connected. When the godet 1 is in operation, at least one thread, at least one fiber and / or at least one band is guided on the outer circumference of the godet jacket 7. The at least one thread, the at least one fiber and / or the at least one band wraps around the godet casing 7. The godet casing 7 is cylindrical. A godet jacket heater 8 is arranged on an inside of the godet jacket 7, by means of which the godet jacket 7 is heated when the godet 1 is in operation. The godet jacket 7 encloses the godet jacket heater 8 in a front area B of the godet 1. That is, the godet jacket 7 is located exactly above the godet jacket heater 8.

In the embodiment shown, the godet jacket heater 8 is an induction heater. In the embodiment shown, 4-zone heating is used in particular. As a result, different areas of the godet 1 can be heated differently. Alternatively, the godet jacket heating 8 can also have only one zone or a different number of zones.

The godet drive motor 2 is arranged in a section A of the godet 1, which is part of the region B of the godet 1 enclosed by the godet jacket 7. The godet drive motor 2 is thus arranged in the same axial area of the godet 1 as the godet jacket heating 8.

The second bearing 42 of the motor mounting 4 is also arranged in the area B of the godet 1, which is enclosed by the godet jacket 7, and thus directly in the area of the load that occurs.

In the embodiment shown, the motor mounting 4 is at the same time the godet jacket mounting.

The godet drive motor 2 and the motor mounting 4 are arranged in the interior of a carrier 9 of the godet 1. In the embodiment shown, the carrier 9 is designed to be rotationally symmetrical.

A stator 22 of the godet drive motor 2 is attached to an inner wall of the carrier 9. The godet drive motor 2 is therefore located, together with its two bearing points, in the interior of the godet jacket 7.

The godet jacket heater 8 is located above the carrier 9 and around a carrier insert 91. The rotor 21 of the godet drive motor 2 is held on the drive shaft 5 with inner rings of the ball bearings 41, 42. The stator 22 of the godet drive motor 2 is held in a carrier bushing with outer rings of the ball bearings 41, 42.

The carrier 9 has an annular cross-section, that is to say it is hollow on the inside, so that the godet drive motor 2 can be accommodated therein. In the embodiment shown, the carrier 9 consists of aluminum.

The carrier 9 has a carrier insert 91 with a smaller external cross-section and a carrier attachment 92 with a larger external cross-section.

The carrier insert 91 has a length C. It is arranged in a region of the godet 1 which is enclosed by the godet casing 7, the carrier insert 91 being provided around the drive shaft 5. The carrier insert 91 is located between the godet drive motor 2 and the godet jacket heater 8.

In the embodiment shown, two Teflon rings 15, 16 are applied to the carrier 9 at a distance from one another, which create a distance between the carrier 9 and the godet jacket heater 8. At this distance there is air 14.

The carrier attachment 92 is located on the front side of the godet jacket 7 and thus in the area not enclosed by the godet jacket 7.

In the embodiment shown, an engine cooling system is integrated as a fluid cooling system 3 in the material of the carrier 9, that is to say in the cylinder wall of the carrier 9. The fluid cooling 3 extends almost over the entire longitudinal extent of the carrier 9. That is to say, in the embodiment shown, the fluid cooling 3 is provided both in the carrier insert 91 and in the carrier attachment 92. The fluid cooling 3 is therefore provided in any case in an area of the carrier 9 located between the godet drive motor 2 and the godet jacket heating 8.

The fluid cooling 3, like the godet drive motor 2 and the motor mounting 4, is thus located in an area enclosed by the godet jacket 7. In the embodiment shown, the fluid cooling system 3 is a water cooling system which is supplied with water via a water connection 31 which leads into the godet 1 at a region of the godet 1 remote from the godet jacket 7.

By the carrier insert 91 running between the godet drive motor 2 and the godet jacket heater 8, the godet drive motor 2 is at least partially shielded from the thermal radiation of the godet jacket heater 8 and additionally cooled by the fluid cooling 3 running in the material of the carrier insert 91.

The carrier 9 can be seen in a perspective top view in FIG. The carrier insert 91 is cylindrical and has a smaller diameter than the carrier attachment 92. The carrier attachment 92 adjoins the carrier insert 91.

In the embodiment shown, the fluid cooling 3 is formed by a cooling coil 30 shown in FIG. 3, for example.

The cooling coil 30 has a coiled tube with a flow 31 and a return 32 for a cooling fluid. In the embodiment shown, the supply line 31 and the return line 32 lie next to one another, being at the same distance from one another in the course of the coiling of the coiled tube. At the beginning of the coiled tube, connections for the flow 31 and the return 32 are provided. At one end 33 of the coiled tube this is deflected, so that the flow 31 and the return 32 are connected to one another here.

The supply line 31 and the return line 32 of the cooling lie next to one another in the same cylindrical plane of the carrier 9.

In the embodiment shown, the coiled tube is a steel tube which is cast into the material of the carrier 9.

In other, not shown embodiments of the present invention, at least one further coil, in which a medium other than the cooling fluid is guided, can run parallel to the coiled tube of the cooling system, in the material and / or on an inner wall of the carrier 9. Thermal sensors 81 are provided in or under the godet jacket 7. The connection cables of the thermal sensors 81 are connected to a measured value transmitter 80. In the exemplary embodiment shown, the measured value transmitter 80 has a rotatable part 82 which is fastened to the drive shaft 5, and a stationary part 84 which is fastened in the carrier 9. Between the rotatable part 82 and the stationary part 84 of the measured value transmitter 80 there is an air gap 83 through which a signal is transmitted.

A fan wheel 12, which rotates with the drive shaft 5, is seated on the drive shaft 5, at one end region of the carrier 9, but still inside the carrier 9.

A seal 13 is arranged on the drive shaft 5 between the bearing 42 and the fan wheel 12.

Claims

Claims

1st godet (1), which has a godet drive motor (2), a motor bearing (4), a rotatably mounted godet drive motor (2) driven or drivable, arranged in the middle of the godet (1) and in the axial direction of the godet ( 1) aligned drive shaft (5), a rotor (21) of the godet drive motor (2) being attached to a peripheral area of the drive shaft (5), a godet jacket (7) connected to the drive shaft (5), one of the godet jacket (7) has enclosed godet jacket heating (8) and at least one cooling, characterized in that at least part of the godet drive motor (2), the motor mounting (4) and at least one fluid channel of the cooling in a section (C) of an area enclosed by the godet jacket (7) (B) the godet (1), in which the godet jacket heater (8) is also arranged, are arranged.

2. Galette according to claim 1, characterized in that the at least one part of the godet drive motor (2) and the motor mounting (4) are arranged in an interior of a carrier (9) and the at least one fluid channel between the godet drive motor (2) and the godet jacket heater (8) runs through the material of the carrier (9).

3. Galette according to one of the preceding claims, characterized in that the cooling has a coiled tube with a supply line (31) and return line (32) arranged next to one another for a cooling fluid.

4. Galette according to claim 3, characterized in that the flow (31) and the return (32) are side by side in the same cylindrical plane in the material and / or on an inner wall of the carrier (9), and / or that the flow (31) and the return (32) lie next to one another in cylindrical planes that are stepped relative to one another in the material and / or on an inner wall of the carrier (9), and / or that the flow (31) and the return (32) on a conical surface plane lie in the material and / or on an inner wall of the carrier (9).

5. Galette according to claim 3 or 4, characterized in that the coiled tube is a steel tube which is cast into the material of the carrier (9).

6. Galette according to one of claims 3 to 5, characterized in that parallel to the coiled tube of the cooling at least one further coil, in which a medium other than the cooling fluid is guided, in the material and / or on an inner wall of the carrier ( 9) runs.

7. Galette according to one of claims 2 or 4 to 6, characterized in that the carrier (9) is made of metallic and / or mineral material.

8. Galette according to one of claims 2 or 4 to 7, characterized in that the carrier (9) has a carrier insert (91) which is sunk into the region (B) of the godet (1) enclosed by the godet jacket (7), and a carrier attachment (92) on which the godet casing (7) rests.

9. godet according to claim 8, characterized in that between the godet jacket heating (8) and the carrier (9) by at least one spacer (15, 16) a distance is made in which there is air (14).

10. Galette according to one of claims 2 or 4 to 9, characterized in that a fan wheel (12) which rotates with the drive shaft (5) is seated on the drive shaft (5) within the carrier (9).