DE2158065B2 - Device for the heat treatment of threads - Google Patents

Description

a continuous heater with a circulating heat transfer medium, z. B. oil, his or the like. the The temperature of the heating surface of the first heating element can be regulated in the usual way in a desired manner or be adjustable in some other way.

Some advantageous developments are described in the subclaims.

By providing according to claim 2 that the heating surface of the second heater on the of the The heating surface of the first radiator is located on the side of the second radiator facing away from it, is the one on the second Filament adjacent to the heating surface is not exposed to heat radiation from the heating surface of the first heating element, so that its heat treatment does not depend on its radiant heat absorbing properties.

The measure according to claim 3 makes it possible by choosing the length and / or cross-sectional constriction desired temperature differences between the Heizflärhen of the first and the second radiator achieve. It is structurally particularly simple to provide the first and the second according to claim 4 To connect radiators in one piece with each other. This also creates joints between the first and second radiators and the normally metallic bridge avoided that too Fluctuations in the heat flow.

If, based on the measure according to claim 3, a greater temperature difference between the first Radiator and second radiator is desired, you can expediently the measure according to claim 5 provide. In many cases, the bridge can also expediently have a lower thermal conductivity than that Have the material of the first radiator. For example, the bridge can be made of a metal of low thermal conductivity or made of ceramic or the like and the first and second radiators from well thermally conductive metal.

In many cases it is desirable to have the heat transfer from the first to the second Radiator for the purpose of setting or regulating the temperature of the heating surface of the second radiator can change. This can advantageously be done in a device according to claim 3 in that according to Claim 6, the length of the thermally conductive bridge is adjustable. One also for the establishment after Claim I a suitable possibility of adjusting the heat transfer is, according to Claim 9, in that the distance between the first and second radiators is adjustable.

It is also often desirable to adjust the temperature of the heating surface of the second radiator in terms of To regulate maintenance of an approximately constant temperature. Based on the measure according to claim 1 provides an advantageous solution for this according to claim 10 that the second radiator with one on one stationary support attached bimetal strip is mechanically and thermally connected to the second Moves the radiator closer to the first radiator as the temperature decreases. Moved accordingly the bimetallic strip moves the second heating element away from the first heating element as the temperature increases, so that an approximately constant temperature of the heating surface of the second heating element is regulated.

It when the second heating element is designed in the form of a plate according to claim 7 is particularly favorable. Man can then form it entirely or essentially as a massive metallic body, the one correspondingly has a large heat capacity, so that it cannot cause rapid temperature fluctuations and thereby the temperature constancy of the heating surface of this radiator is improved.

However, it is also possible and in particular with contactless heating of the threads or filaments expedient to design the radiator according to claim 8 in such a way that it is a metallic tube has, the outside of which can be heated by the first radiator and through the interior of which the or the

lü warming threads can be passed through. It is true known to use thread tubes for the heat treatment of a thread in a block through which the thread is passed through (FR-PS 15 53 503). However, these pipes are not used by a radiator heated, which itself is used for the heat treatment of a thread.

In some cases it can also be provided that a third heating element is provided by means of the second heating element in principle the same way as the second radiator is heated by the first radiator.

Exemplary embodiments of the invention are shown in the drawing. It shows

1 shows a device in a schematic representation for crimping and shrinking a thermoplastic:> Thread,

F i g. 2 is a view of the two radiators in FIG. 1 in the direction of arrow A,

F i g. 3 shows a variant of FIG. 2,
F i g. 4 shows a variant of FIG. 3,
J ^1. ' F i g. 5 shows a further variant of FIG. 2,
F i g. 6 shows a further variant of FIG. 2,
F i g. 7 is a front view of a heating device for the simultaneous heating of three threads at different temperatures;
i ^r ! Fi g. 8 shows a variant of FIG. 7.

In the drawing, corresponding parts are provided with the same reference numerals.

The device shown in Fig. 1 is used to crimp a thermoplastic thread by false-11) twist, whereby the thread is subjected to a shrink treatment after the false twist.

The thread 15 is fed from a supply reel, not shown, by means of a driven pair of rollers 10 is pulled off at constant speed and passed into π a field in which he has a wrong thread is issued by means of a rotating tube 11 (false-wire spindle) rotating at high speed. In the running direction of the thread, a twist stop device 12 is connected upstream of the rotary tube, which prevents it from migrating outwards "> o prevents the twist of the thread from the twist field, as well as a heating plate forming a first heating element 13, which can be heated by means of an electrical heater 14 so that its contact with the thread 15 serving heating surface 16 has a constant, >> relatively high working temperature during operation, for example a temperature of 220 to 240 ° C.

The false twist imparted to the thread in the twist field

is thermally fixed by the heating that takes place by means of the first heating element. The string

>> »is made from the swirl field by means of a pair of rollers 17 peeled off and then passes through a shrinking field, in which it is heated again and around one can shrink a predetermined percentage and from welci.em it by means of the driven pair of rollers 19

fi. withdrawn and to a Aufwir.despule not shown is forwarded.

A second heating element 20 is arranged in the shrinking field, and the thread 15 is attached above its heating surface 21

this runs adjacent. This second heating area 21 has a considerably lower temperature than the heating surface 16. For example, the heating surface 21 have a temperature of 160 to 180 ⁰ C.

The second heating element 20, which consists of a solid metallic plate, is of the first heating element 13 separated by an air gap and arranged so that its rear side of the heating surface 16 of the facing the first heating element 13 in parallel and furthermore the heating surface 21 of the second heating element 20 is turned away from the first heating element 13. The second radiator 20 is only used by the first Heating element 13 heated by thermal radiation and possibly also by air convection. The distance between the second heater 20 and the first heater 13 is made so that the shrink treatment the required temperature of the heating surface 21 of the second heating element 20 is set.

According to FIG. In this exemplary embodiment, the width of the second heating element 20 corresponds to the width of the first radiator 13. As shown in FIG. 3 is shown in an example, can in many cases with Advantage, the width of the second heater 20a different - larger or smaller - than that of the first radiator 13. In Fig. 3, the width of the second heating element 20a is considerably smaller than the width of the first heating element 13. With particular advantage here, the thread 15 on the heating surface 16 of the first heater 13 are guided so that it is at a distance to the side of the second heater 20a, as shown in FIG. 3 is shown. In Fig. 3 is also one of the adjustment of the temperature of the heating surface 21a of the Second heater 20a serving manual adjustability of the distance of the second heater 20a from the first heating element 13 is provided by the second heating element 20a by means of a fixed to it connected arm 22 is pivotably articulated to a stationary support 23 on the machine in question and the angular position of the arm 22 by means of an adjusting screw 24 against the action of a compression spring

25 is adjustable. As a result of this pivotability, positions of the second heating element 20a can also be set in which its rear side is not exactly parallel to the heating surface 16 of the first heating element 13. However, this does not interfere with the temperature uniformity of the heating surface 21a of the second Radiator 20a because the relatively large metallic mass of the second radiator 20a is its temperature is evened out and its heating surface 21a on the side facing away from the first heating element 13 of the second radiator. If, however, as the heating surface of the second heater 20a, the Heating surface 16 of the first heating element 13 is intended to serve on the opposite surface of the second heating element 20a, it is advisable to guide the second heating element 20a by means of a parallel guide or straight guide so that that its heating surface to the heating surface 16 of the first heater 13 always remains parallel.

The embodiment of Figure 4 differs differs from the embodiment according to FIG. 3 in that the second heating element 20a by means of a straight Bimetallstrcifens 26 is held on a stationary support 23 as shown, so that the distance of the second heater 20a from the first heater 13 as a function of the temperature of the bimetallic strip

26 by bending the bimetal strip accordingly changes. The bimetallic strip 26 is arranged and designed so that the distance between the first and second radiators with decreasing! Temperature of the bimetal strip 26 and thus mi decreasing temperature of the heating surface 21a de; second heater 20a reduced and vice versa, se that a regulation of the temperature of the heating surface 21a to an approximately constant temperature value results. The bimetallic strip 26 is in a thermally conductive connection with the metal de < second heating element 20a and thus assumes approximately the same temperature. Possibly. the bimetal strip 26 be thermally insulated from the ambient air, since its own temperature is as close as possible to its own temperature of the second heater 20a corresponds.

In the embodiment according to FIG. 5, two second heating elements 20 * and 206, separated by air spaces of different sizes, face the first heating element 13, the heating surfaces 21a and 2it of which assume different temperatures, these plate-shaped heating elements 20a and 20A being heated solely by the heating plate 13 by radiation and air convection. In a manner not shown in detail, the thread 15 is first passed over the heating surface 16, then over the heating surface 20a and then over the heating surface 206, or it can be three different threads.

In the embodiment according to FIG. 6, the second heating element 20c is designed as a metallic tube, which through the heating surface 16 of the first heater 13 by radiation and possibly air convection is heated. The thread 15 to be heated in this tube 20c for the purpose of shrinking, for example - the before or after runs over the heating surface 16 - runs through the pipe 20c approximately in it geometric longitudinal axis. This tube 20c can advantageously be made of metal that is as good a heat conductor as possible, for example aluminum or copper.

The heating device according to FIG. 7 has a metallic plate 27 of the illustrated cross-sectional profile, which extends perpendicular to the image plane with a constant cross-sectional profile. On her one On its long side, it has an edge bead 29 which extends over its entire length and is approximately circular in shape Cross-section, which has a central, cylindrical bore in which an electrical heating element 30 is arranged.

The one-piece area 31 of this plate 27 of the same thickness corresponds in the sense of the present invention to three heating elements 13a, 20e and 20i which are connected to one another by bridges 32 by having three heating surfaces 16a, 21e and 21 ^ different operating temperatures for heating the thread or threads 15 . These threads 15 can, for example, be separate individual threads which are to be twisted together after the heat treatment, or it can be a single thread which slides successively over the three heating surfaces 16a, 21e and Hf. It is important that these three heating surfaces have different temperatures at the points where the thread or threads 15 are in contact with them, such that the first heating surface 16a has the highest temperature and the third heating surface 21Ai the lowest temperature.

The plate 27 can expediently consist of a metal with relatively poor thermal conductivity, for example Stole. By the heating element 30 on the second and third heating surface 20e and 20 / Applied side of the first heating surface 16a is arranged, there is a heat flow which the mentioned different temperatures of the first,

causes second and third heating surface. The temperature differences depend on the distances between the points, which can be changed if desired which the thread or threads 15 slide and the thermal conductivity of the plate 27 and can also influenced by any other suitable measures and set to certain values be, for example, by the cross-sections of the bridges connecting the heating surfaces according to FIG 32 constricts by incisions 33 or by, as indicated by dash-dotted lines in Fig. 7, the Areas having heating surfaces 16a, 20e and 20A by bridges 32 of other material from one another separates that has a lower thermal conductivity than that

Areas of the plate 27 having heating surfaces. By choosing the right material for the bridges and / or choice of cross-sections and / or effective, if desired also adjustable lengths of the bridges can consequently also set the desired temperature differences between the individual heating surfaces will. Other measures are of course also conceivable for this purpose.

The heating surfaces of the radiators can have known designs, for example in Direction of thread transport be slightly convex. The heating surfaces can be as required Have lengths, and have the same or unequal lengths as required.

For this purpose 2 sheets of drawings

Claims (10)

Patent claims: 1. Device for the heat treatment of continuously moving threads with a first heating element and at least one second heating element, the working temperature of the heating surface of the first heating element being higher than the working temperature of the heating surface of the second heating element, characterized in that the second heating element (20; 20a; 20b; 20c) faces the heating surface of the first heating element (13) at a distance separated by an air gap and can be heated by means of the first heating element (13). 2. Device according to claim 1, characterized in that the heating surface of the second heating element (20; 20a; 206; on the side of the second heating element facing away from the heating surface (16) of the first heating element (13) is located. 3. Device for the heat treatment of continuously moving threads with a first heating element and at least one second heating element, the working temperature of the heating surface of the first heating element being higher than the working temperature of the heating surface of the second heating element, characterized in that the first (13aJ and the second heating element (20e, 20f) are connected to one another via a thermally conductive bridge (32) and the heating surface of the second heater is heated at least essentially by the heat flowing from the first heater over the thermally conductive bridge into the second heater. 4. Device according to claim 3, characterized in that the first and the second heating element are integrally connected to one another. κ 5. Device according to claim 3, characterized in that the thermally conductive bridge consists of one There is material, which has a lower thermal conductivity than the material of the second heating element Has. 6. Device according to claim 3 or 5, characterized in that the length of the thermally conductive Bridge is adjustable. 7. Device according to one of the preceding claims, characterized in that the second heating element (20; 20a; 20b; 20e, 20f) is plate-shaped. 8. Device according to one of claims 1 or 3 to 7, characterized in that the second heating element has a metallic tube (20c) , the outside of which can be heated by the first heating element (13) and through the interior of which the thread or threads to be heated ( 15) can be passed through. 9. Device according to one of claims 1 to 3 or 5 to 8, characterized in that the π distance between the first (13) and second heating element (2OaJ is adjustable. 10. Device according to one of claims 1, 2, 7 or 8, characterized in that the second heating element (2OaJ with tinem on a stationary wi support (23) attached bimetal strip (26) is mechanically and thermally connected, which the second heating element ( 2OaJ moves closer to the first heating element (13) with decreasing temperature. ·>■> The invention relates to a device for the heat treatment of continuously moving threads according to the preamble of claim 1. During the production, texturing or other treatments of textile threads, this often results the textile machines in question the need to heat the thread or threads. Often occurs to Example of the case that a thread continuously moved on a textile machine two consecutive or more heat treatments are subjected to different temperatures, for example at False twisting and subsequent shrinking of threads, during stretching or other treatment processes. Or there is the case that two or more threads to be twisted together on the machine in question before they are twisted are heated to different temperatures, for example when the threads concerned are thermally shrunk and consist of different thermoplastic materials. If up to now you had a thread on a textile machine in succession at different temperatures heated or multiple threads to be twisted together before twisting If different temperatures were heated, so one always proceeded in such a way that to generate each Working temperature provided a separate heating device, for example an electrically heated heating plate and an electrically heated heating roller (DE-OS 18 13 196). Since such textile machines in general have a relatively large number of jobs where threads are simultaneously corresponding in themselves To be treated thermally, it had to contain a very large number of such heating devices. The economic and technical effort required for this is very large and makes the relevant one more expensive Machine considerably. It is therefore the object of the invention to reduce the structural and technical complexity for the heating devices to greatly reduce such facilities. Starting from a device according to the preamble of claim 1, this object is according to the invention achieved in that the second heating element of the heating surface of the first heating element in the Distance faces separated by an air gap and by means of the first radiator is heatable. The same object can be achieved on the basis of a device according to the preamble of claim 1 according to the invention also solve in that the first and the second heating element via a thermally conductive bridge are interconnected and the heating surface of the second heater at least substantially through the one flowing from the first radiator over the heat-conducting bridge into the second radiator Heat is heated. Since the first radiator heats at least one second radiator, only one is required heat source used to heat the first radiator. The second radiator doesn't need any separate heat source, since the heat source that heats it is the first radiator, which anyway is available. It is therefore at least half the number in textile machines with such devices the previously required heating devices saved. The heat source heating the first radiator can be of any conventional type, for example can it be an electrical resistance heater,