EP0854216A1 - Roller for transporting, guiding and heating a travelling synthetic yarn - Google Patents

Abstract

A heated roller to guide and feed a moving synthetic filament has a radiant heater (6) as a heating coil (19) radially round the carrier (4) at a gap from the roller mantle (1). The coil (19) has a number of windings (26) with unequal gaps between them.

Description

The invention relates to a godet for conveying, guiding and heating a running synthetic thread according to the preamble of the claim 1.

Such a godet is, for example, from the German Utility model 1694542 known.

During the heat treatment of a running thread using a thread promoting godet, it is necessary that the rotating godet jacket uniform surface temperature over the entire circumference having. For this purpose, the godet jacket is replaced by an inside of the Galette arranged and essentially parallel to the godet jacket aligned radiant heater is heated.

Because the thread repeats the godet jacket several times along an occupancy length wraps around, it is also necessary that the godet jacket along the Length of coverage an essentially constant surface temperature having. However, this occurs particularly in the end areas of the Galette greater heat loss through heat conduction or through flowing cooling air.

In DE 195 32 036 C1 this problem is solved in that an adjustable between the radiant heater and the godet jacket Cover is arranged so that zones arise in the godet that be heated up more or less depending on the adjustment. This However, arrangement has the major disadvantage of a bad one Efficiency, since the cover is permanently covered by the radiant heater only shields generated heat from the godet jacket.

The arrangement according to US 4,880,961 also includes a mode of operation of the radiant heater with poor efficiency, since the Radiant heaters generated heat with different walls Wall thickness must penetrate to heat the godet jacket.

Accordingly, it is an object of the invention, a godet of the beginning mentioned type in such a way that the godet jacket by means of Radiant heat is heated such that the occupancy length of the godet has a substantially constant surface temperature.

Another object of the invention is to provide a godet which the energy generated by the heater without significant losses Heating of the godet leads.

This object is achieved by the features of claim 1, claim 4 or claim 11 solved.

Further advantageous developments of the invention are in the Subclaims defined.

The particular advantage of the invention is that the radiant heat depending on the temperature distribution on the godet jacket he follows. Thus, especially in the end areas of the godet higher heat radiation from the radiant heater. For this is the Radiant heater executed according to claim 1 with a heating coil, the along their length unequal distances between adjacent turns having. Thus, the zones in the godet due to Conduction of heat requires a greater heat input, a relative Small distance between the turns of the heating coil.

Any temperature profiles can be achieved using the godet according to the invention realize along the length of occupancy of the godet surface. Here heat radiation can be determined both by the number of turns Heating coil as well as by designing the distances between neighboring turns can be advantageously predetermined.

Another advantage of the godet according to the invention, especially after Claim 4 is that the godet jacket through the Heat radiation and is heated by convection. Here the Effect exploited that within the godet by rotation an airflow in the between the Galette jacket and the radiant heater formed annulus. This air flow leads to a transfer of energy from the heater to the godet jacket by convection. It has been found that at such an arrangement of the radiant heaters in one area work below the usual temperature range of 800 to 1,000 ° C can.

In a development of the invention according to claim 2 Heating coil of the radiant heater embedded in a protective tube, which is attached helically to the carrier. This will make an immediate Contact with the heating coil, for example, when changing one Avoid godet jacket.

To embed the heating coil, it is advantageous according to claim 3 or 4, if there is an electrical one between the support and the heating coil Insulation is arranged. This ensures that the heating coil is attached directly to the periphery of the carrier and their radiant heat can drop unimpeded in the direction of the godet casing. This The exemplary embodiment is preferred for heating the godet casing higher temperatures in the range of 300 ° C suitable because of the The amount of energy transferred by convection is particularly large. Of the prevailing between the godet jacket and the heating coil Air flow is in direct contact with the heating coil.

In order to increase the heat energy given off by the radiant heater it is advantageous if, according to the exemplary embodiment according to claim 5 a reflector is arranged between the support and the radiant heater is. Furthermore, this also gives the inside Thermal energy limited. Especially to avoid high Storage temperatures, it is advantageous if between the reflector and thermal insulation is arranged on the carrier.

According to a further preferred embodiment according to claim 8 is an additional radiant heater opposite the inner face of the Galette jacket attached to the carrier. This will make an additional one Heat input in the outer edge area of the godet casing and in the end face generated. This additional radiant heater thus brings heat energy in the area of the godet, which is the strongest Cooling is exposed.

In the arrangement according to the invention it has been shown that one low surface temperature of the heating coil in the range of 500 to 800 ° C is sufficient to bring the godet jacket to a temperature of approx. To heat 250 °.

The design of a godet according to claim 10 or 11 is especially for godets with a relatively long occupancy length of approx. Can be used from 250 to 300 mm. The different in the zones of the godet The thermal energy introduced is independent of each other adjustable radiant heater generated directly. By heating the Galette jacket with several radiant heaters also has the advantage that a finely graduated surface temperature can be set and a sensitive control of the surface temperature with fast Standard times are possible. The zones can be the same widths or have different widths, the turns in the Heating coil with the same or different distances from each other can be arranged within a zone.

According to a preferred exemplary embodiment, the Invention according to claim 3 between the adjacent radiant heaters Arrays arranged, which are attached to the carrier and for Godet jacket has an air gap of a few millimeters. Thereby there are limited heat zones depending on the respective assigned radiant heater are heated.

It is particularly advantageous if, according to claim 13, each zone a temperature sensor is arranged on the godet jacket and the respective radiant heater in a control loop depending on the measured temperature can be regulated. Here there is the possibility that a temperature profile of the occupancy length by means of the control device can be specified.

Another possibility for controlling the thermal energy is given according to a preferred embodiment according to claim 14. The heating coils of the radiant heaters have different heating lengths, so that their specific load can be varied. In particular in the radiant heaters arranged at the end region of the godet, which are shorter than the heating spirals of the radiant heaters in the central region of the godet, a specific load of approximately 5 watts per cm ^{2 is} achieved.

Further advantages, features and possible uses of the invention are now based on an embodiment with reference to the attached drawings explained in more detail.

Fig. 1 und 2

jeweils schematisch einen Längsschnitt durch eine Galette mit einem Strahlungsheizer;

Fig. 3 und 4

jeweils schematisch einen Längsschnitt durch eine Galette mit mehreren Strahlungsheizern.

Show it:

1 and 2

each schematically shows a longitudinal section through a godet with a radiant heater;

3 and 4

each schematically shows a longitudinal section through a godet with several radiant heaters.

1 and 2 is a schematic longitudinal section through a godet shown. Insofar as nothing is said, the following description applies to both figures. The godet has a jacket 1, the front on free end of the godet is firmly connected to an end wall 25. In the In the middle, the end wall 25 is concentric with the jacket 1 aligned collar 9 on. The end wall 25 and the collar 9 are penetrated by a bore 10, which is at the end of the collar enlarged conically. In the bore 10 is the end of a drive shaft 3 inserted with a cone 8 in a form-fitting manner. Through a Bracing element 5 is the end wall 25 with the collar 9 firmly on the Cone 8 of the drive shaft 3 clamped. The drive shaft 3 is on projecting opposite end in a godet holder 2 with the Bearings 11 and 13 stored. The drive shaft 3 becomes pot-shaped put on godet jacket 1 driven by a drive 12. Of the Drive 12 is also attached to godet holder 2.

Between the cantilevered part of the drive shaft 3 and the Drive shaft 3 cup-shaped surrounding godet jacket 1 is a tubular carrier 4 arranged, which is fixed to the godet holder 2nd connected is. The tubular support 4 is from the cantilevered part the drive shaft 3 and the collar 9 penetrated. Opposite the End wall 25, the carrier 4 is arranged at a distance. Likewise, a ring 28 is formed between the godet casing 1 and the carrier 4. A radiation heater 6 is arranged in the ring 28. The radiant heater 6 has a heating coil 19 which is helical in several Windings 26 is arranged around the carrier 4. The heating coil 19 is connected to a connection 14 arranged on the godet holder 2. over the connection 14 is the electrical supply to the radiant heater.

In the embodiment of FIG. 1, the heating coil 19 is in one Protection tube 7 inserted. The protective tube 7 thus wraps around the carrier 4 helical and is attached to the carrier 4.

The turns of the protective tube 7 with the heating coil 19 are around the carrier 4 arranged that the distances between adjacent Turns in the end regions of the carrier are smaller than the distances adjacent turns in the central area of the carrier. Between the Protective tube 7 and the inner diameter of the godet casing 1 is a Distance formed in the order of 6 to 15 mm. Through the different winding distribution over the heating length of the Radiant heater is achieved that the areas of the godet that the areas of the steel heater with small distances between the Opposing turns 26 are heated more. Thus, the Areas that are more exposed to heat loss, more Thermal energy supplied.

In order to direct the heat radiation towards the outside to the godet jacket 1 conduct, it is advantageous if, as in Fig. 1 in the lower half of the picture shown, between the protective tube 7 and the carrier 4, a reflector 17th is arranged. To prevent excessive heat energy from being used Drive shaft 3 and thus to the bearing 11 is between the Reflector 17 and the carrier 4, a thermal insulation 18 attached.

In FIG. 2 there is electrical insulation 20 on the circumference of the carrier 4 appropriate. For its part, the insulation has a circumference helical circumferential groove 31. The turns 26 of the groove 31 are at different distances along the length of the carrier trained to each other. Especially towards the edge of the godet casing the turns are arranged at a smaller distance from each other than in the middle area of the godet jacket. In the groove 31 is the Heating coil 19 inserted. The heating coil 19 thus has compared to Annulus 28 or the godet jacket 1 no protective jacket. At this The share of heat transfer by convection can be arranged increase significantly. The convection in the annular space 28 is due to the the rotating godet jacket 1 favors air flow. Here can the heat losses that occur at higher speeds due to im Air currents that develop at the edge essentially arise be compensated. Furthermore, the energy of the radiation heater introduced into the godet jacket 1 even more efficiently.

In Fig. 3 and Fig. 4 is a longitudinal section of a schematic Galette shown, whose godet jacket by several in a row arranged radiant heater is heated.

The structure of the godet of FIG. 3 is essentially the same Structure of the godet from Fig. 1, so that on the description of Fig. 1st Reference is made. 3 are the on the carrier 4 Radiant heaters 6.1, 6.2, 6.3, 6.4 and 6.5 arranged one after the other. The radiation heaters 6.1 to 6.5 each consist of one Heating coil 19, which is embedded in a protective tube 7. The protective tube 7 wraps around the carrier 4 helically. Each of the heating coils 19 is via connection 14 with an electrical supply unit connected. Between the neighboring radiant heaters 6.1, 6.2 and 6.2, 6.3 and 6.3, 6.4 and 6.4, 6.5 is a web 16 on each Carrier 4 attached. The webs 16 are disc-shaped around the carrier 4 arranged, between the outer diameter of the webs 16 and the An air gap 27 is formed in the godet jacket 1. The air gap is 27 compared to that between the radiant heaters 6 and the godet jacket 1 trained distance much smaller and is only a few millimeters.

In the arrangement shown in Fig. 3, the turns of the Protection tube 7 an equal distance, so that each by two Adjacent webs formed heat zone 29.1 to 29.5 evenly over the length of the heating coil 19 is heated. To create zones, which are heated with higher thermal energy on the godet jacket the lengths of the heating spirals 19 of the individual radiant heaters 6.1 to 6.5 differently. In the arrangement shown in Fig. 3, the Radiant heaters 6.1 and 6.5 each have short heating spirals. This increases the specific load on the heating coil, so that a greater thermal energy of the respective heat zones 29.1 and 29.5 is delivered. The radiation heaters 6.1 and 6.5 are in turn in zones in which greater heat losses occur in the godet jacket.

The radiation heaters 6.1 to 6.5 are with their respective protective tubes 7 via a reflector 17 and thermal insulation 18 on the carrier attached.

However, especially in the end areas of the godet and in particular the end wall 25 of the godet casing 1 in conventional godets relatively large cooling occurs because, on the one hand, the end wall 25 does not or is insufficiently heated and, on the other hand, the end wall 25 is one represents relatively large heat dissipation area is at the free end of the An additional radiation heater 15 opposite the end wall 25 arranged. Above all, this additional radiant heater 15 in the end region of the godet casing 1 and the end wall 25 of the Galette jacket 1 supplied thermal energy so that the energy dissipation in the areas mentioned can be compensated. Through this compensation becomes the area of the outer surface of the godet casing 1 which its occupancy length has an essentially constant temperature, enlarged in terms of its length dimension, so that without increase the constructional length of the godet an increase in the length of occupancy is achievable on the godet.

In the godet shown in FIG. 4, there are again several radiant heaters 6.1 to 6.4 arranged one behind the other on the carrier 4. Here is the heating coil 19 in a provided with thread-like grooves 31 electrical insulation 20 inserted. The electrical insulation 20 is on attached to the carrier 4. Neighboring radiant heaters are also like already described in FIG. 3, separated from one another by webs 16. In each of the heat zones 29.1 to 29.4 thus formed is in each case A temperature sensor 21.1 to 21.4 is assigned to the godet jacket. The Temperature sensors 21.1 to 21.4 are at the end of the Drive shaft 3 arranged measured value transmitter 24 in connection. Of the Measurement data transmitter 24 transmits the measurement data between the rotating ones and the fixed components of the godet. The measurement data are then led to a control device 22. The control device 22 is with a control device 30 connected. The control device 30 takes over the regulation of the energy supply of the radiant heaters 6.1 to 6.4. This makes it possible to put in every single radiant heater Regulate depending on the surface temperature of the godet casing or any temperature profile along the length of the occupancy Set godet casing 1.

Such a control has the advantage that it is material-specific Properties that affect heat flow do not affect have the desired surface temperature of the godet casing.

REFERENCE SIGN LIST

1

Godet jacket

2nd

Godet holder

3rd

drive shaft

4th

carrier

5

Bracing element

6

Radiant heater

7

Protective tube

8th

cone

9

collar

10th

drilling

11

camp

12th

drive

13

camp

14

Connection

15

Radiant heater

16

web

17th

reflector

18th

Thermal insulation

19th

Heating coil

20th

insulation

21

Temperature sensor

22

Control device

23

management

24th

Measurement data transmitter

25th

Front wall

26

Coils

27

Air gap

28

Annulus

29

Heat zone

30th

Control device

31

Grooves

Claims (15)

Galette for conveying, guiding and heating a running synthetic thread with a rotating godet casing (1) and a stationary tubular support (4), the godet casing (1) being placed over the support (4) in a cup-shaped manner and with a radiant heater (6) for heating the godet casing (1), the radiation heater (6) being arranged on the circumference of the carrier (4) at a distance from the godet casing (1),
characterized in that
the radiant heater (6) is a heating spiral (19) with a plurality of turns (26) which radially surrounds the support (4) and has unequal distances between adjacent turns over its length (heating length). A godet according to claim 1,
characterized in that
characterized in that
the heating coil (19) is embedded in a protective tube (7) and that the protective tube (7) is attached helically to the support (4). A godet according to claim 1,
characterized in that
the heating coil (19) is fastened to the carrier (4) without a protective jacket and that electrical insulation (20) is provided between the carrier (4) and the heating coil (19). Galette for conveying, guiding and heating a running synthetic thread with a rotating godet casing (1) and a stationary tubular support (4), the godet casing (1) being placed over the support (4) in a cup-shaped manner and with a radiant heater (6) for heating the godet casing (1), the radiation heater (6) being arranged on the circumference of the carrier (4) at a distance from the godet casing (1),
characterized in that
the radiant heater (6) is a heating coil (19) radially wrapping around the carrier (4) with a plurality of turns (26) and without a protective jacket, and that electrical insulation (20) is provided between the carrier (4) and the heating coil (19). Galette according to one of claims 1 to 4,
characterized in that
a reflector (17) is arranged between the carrier (4) and the radiation heater (6). A godet according to claim 5,
characterized in that
thermal insulation (18) is arranged between the reflector (17) and the carrier. Galette according to one of claims 1 to 6,
characterized in that
thermal insulation (18) is arranged between the carrier (4) and the radiant heater (6). Galette according to one of claims 1 to 7,
characterized in that
an additional radiant heater (15) is attached to the carrier (4) opposite the end wall (25) of the godet casing (1). Galette according to one of claims 1 to 8,
characterized in that
the heating coil (19) has a surface temperature in the range from 500 to 800 ° C. Galette according to one of claims 1 to 9,
characterized in that
several radiation heaters (6.1-6.4), each with a heating coil (19), are arranged one behind the other in a helical shape on the support (4) and that the radiation heaters (6.1-6.4) can be regulated independently of one another. Galette for conveying, guiding and heating a running synthetic thread with a rotating godet casing (1) and a stationary tubular support (4), the godet casing (1) being placed over the support (4) in a cup-shaped manner and with a radiant heater (6) for heating the godet casing (1), the radiation heater (6) being arranged on the circumference of the carrier (4) at a distance from the godet casing (1),
characterized in that
several radiation heaters (6.1-6.4), each with a heating coil (19), are arranged one behind the other in a helical shape on the support (4) and that the radiation heaters (6.1-6.4) can be regulated independently of one another. Galette according to claim 10 or 11,
characterized in that
Adjacent radiant heaters (6.1, 6.2) are separated from one another by a web (16) which is fastened to the support (4) and has an air gap (27) of a few millimeters to the godet casing (1). Galette according to one of claims 10 to 12,
characterized in that
each radiation heater (6.1-6.4) is assigned a temperature sensor (21.1-21.4) on the godet casing (1) and that the temperature sensor (21.1) and the respective radiation heater (6.1) are included in a control loop with a control device (22). Galette according to one of claims 10 to 13,
characterized in that
the heating lengths of the heating coils (19.1-19.4) are different. Galette according to claim 14,
characterized in that
the heating spirals (19.1, 19.4) of the radiant heaters (6.1, 6.4), which are arranged at the ends of the godet casing (1), are shorter than the heating spirals (19.2, 19.3) of the radiant heaters (6.2, 6.3), which are located in the middle area Galette jacket (1) are arranged.

Images