The invention relates to a texturing system, or a thread processing device, with a texturing nozzle for forming a textured thread. A nozzle of this generic type is described, for example, in the German published examined application 20 3 6856. The yarn, entering the nozzle from above, is conveyed by a hot-air flow to a compression part, which is provided with passage apertures, for example in slot form. Due to the lateral escape of the air being blown in, and as a result of the reduction in speed in the passage channel, the continuous filament yarn compresses, and thus also incurs a braking effect. The yarn strip which forms is ejected relatively slowly from the nozzle and cooled. In this situation, a rotating cooling drum can be used, on the surface of which the compressed yarn is laid, whereby, as a result of perforations in the drum, air at a lower temperature is sucked into the nozzle, e.g. ambient air, which has the effect of cooling the yarn.
The invention also relates to the compression part of a texturing system, in particular a BCF texturing nozzle, for high velocities. A compression part of a texturing nozzle according to the conventional design is usually formed from an upper and lower lamellar plate holder and a plurality of lamellar plates.
The texturing air and the yarn enter the compression part of high speed from above, i.e. in the direction of flow of the fibres and air respectively. The air flows in the area of the compression part in impart manner through the slots or intermediate spaces between the lamellar plates in a more or less radial direction, and mostly emerges to the outside at the lamellar plates. This has the effect of reducing the air speed in the longitudinal channel of the nozzle. The yarn is braked as a result and forms a strip, which fills the entire inner diameter of the slotted part, namely the compression part. The strip slides downwards through a strip guide tube to a cooling drum or to a conveying device, in particular a pair of rollers.
The strip formation inside the nozzle is influenced by the flow circumstances and geometric conditions which prevail there. If interruptions occur, or specific parameters on which the strip formation depends are altered, the quality of the thread may change impermissibly.
From U.S. Patent No. 5,653,010, the principle is known of conducting the yarn strip from the texturing nozzle onto a drum and of steering the material flow on the circumferential surface thereof between two rows of needles, which project vertically from the surface. The strip formation in this situation, however, is only influenced at the transition point from the nozzle onto the drum by the conditions which prevail there, which in practice has not led to the desired consistent thread quality.
In EP Application No. 1101 849, it is proposed that the thread be deposited in a drum groove, in order thereby to control the conveyance of the strip better, and at the same time to cool it. In this situation, however, very narrow tolerances are to be maintained in the manufacture of the drum.
A goal of the invention is to design a thread processing device of such a nature that high production at constant thread quality is attained. Additional objects and advantages of the invention are set forth below in the following description, or may be obvious from the description, or may be learned through practice of the invention.
The thread processing device according to the invention makes provision for a texturing system which is followed by at least one drum for the controlled guidance of the thread with the simultaneous imposition of a guiding and cooling air flow, and, if appropriate, also by a second drum for the complete cooling of the thread.
The thread is conveyed through a nozzle by means of heated compressed air into a storage space and there packed to form a very dense strip. This strip is guided through a guide tube to a first, relatively small cooling drum, and there deposited in a groove, which is precisely as wide as the diameter of the strip. The storage space consists of a short tube with a longitudinal slot, and downstream is expanded to such a degree that no strip is formed by the yarn friction alone on the lamellar plates. Due to the precise guidance of the strip on the cooling drum, this (the guidance) dictates the speed and therefore also the density of the strip. The strip is somewhat cooled in the compressed state by the ambient air sucked into the cooling drum, and then raised by a guidance element or an air jet out of the groove and laid on a second larger cooling drum, designed in the manner of the prior art. It there expands by about the factor of 1.5 to 4, and is fully cooled by the ambient air sucked in. The strip is then again stretched to form a thread and drawn off from a mono or duo.
The invention also relates to a method for the formation of a textured thread in a texturing system with a texturing nozzle and a drum connected thereto, whereby the thread is guided on the outlet side of a texturing nozzle at the circumference of a drum in the form of a strip. For preference, technical air means are provided for, characterized in that, at the circumference of the drum, the strip is cooled by effect from the outside, in particular by means of a blower device, for preference through a blow aperture directed onto the thread run.
In addition, a texturing system is proposed with a texturing nozzle and a drum connected thereto, whereby a guidance system for a strip is provided for on the outlet side of a texturing nozzle, at the circumference of a drum, and technical air means are provided for, in particular for the performance of the process, characterized in that a delivery point for cooling air is provided for at one drum at least, for the issue of a conditioning medium to the strip.
According to the invention, a blower device may be arranged at the circumference of the drum, in general terms a cooling device, with which the thread lying on the surface of the drum is cooled and conditioned in a specific and defined manner. In this situation, this initially involves the rapid cooling of the thread strip running on the circumference of the drum; expressed in other terms, a shock cooling effect, by means of a shoe located on the drum in the run-out area of the strip, which is drawn through a system of holes for the provision of a cooling and conditioning medium respectively.
In addition to, or as an alternative to this, it is possible for a climatisation and simultaneous cooling to be achieved over a substantial circumference of the cooing drum for the strip running over the surface of the drum and moving forwards with it, by the arrangement of an air deflection plate in the area of the thread strip on the drum surface, whereby cooled air is conducted at an angle of about 180° onto the circumferential surface following on from the texturing nozzle. The cooled air is introduced in the area of the air deflection plate onto its side which is turned towards the cooling drum. This deflection plate must not hinder the drawing process of the thread before the system is run up to speed, and, if at all possible, is to be designed so as to pivot. The gap between the cooling drum and the deflection plate should for preference not be greater than 5 mm. The area of the deflection plate directed against the operator is for preference to be made of Plexiglas (Perspex), in order for the operating personnel to be able to evaluate the formation of the strip. The arrangement of the deflection plate which favours the flow is necessary in order to avoid pressure losses.
If cooling air is being introduced as the conditioning medium, then provision is to be made for an air flow of about 1,200-2,500 Nm3/h for a two-thread cooling drum, i.e. a cooling drum with two thread strips running parallel to one another imposed on it. The air temperature should be infinitely adjustable and regulatable between 5° C. and room temperature. The cooling device required for cooling the air flow should be designed for a capacity of 2,500 Nm3/h. A temperature of the emerging air of max. 5° C. must be assured at an ambient temperature of up to 50° C. The delivery of the cooling air to the surface of the deflection plate is effected, for example, by means of flexible metal hoses. The deflection plate is to be provided with a row of passage apertures, through which the cooled air can be distributed uniformly over the surface of the drum in the area of the strip or strips. Between the surface of the deflection plate, provided with passage apertures, and the feed line for the cooled air, a cover is to be arranged, which has an aperture on the inlet side for the delivery of the air, and is open on the outlet side to the passage apertures, in which situation screening is necessary against the ambient air. The cooling drum is for preference to be subjected to air over what is referred to as a blowing angle of 180° to 240°. This means that the air deflection plate surrounds the drum over an angle from 180° to 240°, with a distance of, for preference, between 3 and 5 mm from the cooling drum surface.
The passage apertures or holes in the shoe referred to heretofore, at the outlet point of the strip on the cooling drum or in the air deflection plate are, for preference, to be designed as multi-row, and extend at least over the width of a groove in the surface of the cooling drum in which the strip comes to lie. The hole diameter is between 0.5 and 1 mm. As media for the cooling or conditioning of the thread strip, consideration may be given to:
Air
Water mist
Water
CO2
N2
Spin Finish (water-oil emulsion)
With a drum diameter of, for example, 400 mm, a high texturing capacity can be achieved, with a texturing speed of up to 5,000 m/min.
The attempt should be made to achieve a conditioning of cooling of the thread strip over up to ¾ of the circumference of the drum. By this measure, at least a desired temperature and, for preference, a specific relative humidity can be attained of the thread strip finally running off the surface of the cooling drum.
If two cooling drums are present, the first is to be relatively small in diameter and therefore manufactured economically and more easily with the required precision of concentricity. It can be optimized with regard to its function in respect of the depositing of the strip (very fine perforation in the screen) and lateral strip guidance. The second cooling drum is not critical with regard to precision of concentricity and precision of rotational speed, and can therefore also be economically manufactured. The diameter of this drum, delimited only by the machine layout, allows for a substantial cooling length, and therefore a very high speed potential. The system imposes far fewer high demands on the mutual positioning of the key components than, for example, the Rolltex or the ZIP process from Honeywell.
Thanks to the cooling lengths being of hardly any limit due to the corresponding machine layout, a capacity of 5000 m/min is achievable.
In the texturing device, in particular with a maximum length of the compression part of 60 mm, a guide part with maximum the same length is connected, along which the texturing yarn can be guided in the form of a strip to the surface of the drum, and, subsequent to this first guide part, after a deflection, a second guide part is provided along the surface of the drum, by means of which the textured yarn is guided, on the one hand, in the radial direction as well as in the axial direction of the drum. It is also possible for a third guide part to be connected. By means of the last two parts, a medium can be introduced to the thread strip concerned.
The invention is described in detail hereinafter on the basis of the drawings. These show:
a: A plan view of a texturing system in diagrammatic representation;
b: A meridian view through a part of a drum wall with a strip in transverse section;
c: An overview of the relative location of a nozzle block, and of the first and second drum in relation to each other;
a: Cooling devices, and cooling air delivery devices respectively;
Reference will now be made in detail to embodiments of the invention, examples of which are illustrated in the drawings. Each embodiment is presented by way of explanation of the invention, and not meant as a limitation of the invention. It should be apparent that modifications and variations can be made to the embodiments described herein without departing from the scope and spirit of the invention.
The nozzle 10 is shown in
Underpressure pertains inside the drum, so that cooling air can enter through the strip running on the surface of the drum 22 and through the perforation into the interior of the drum. Due to the narrow guidance arrangement, on the one hand due to the lateral channel walls in a channel, and on the other due to the concentrated air emerging through the floor of the channel, the strip is prevented from making movements relative to the drum. It is therefore guided on a trajectory at the circumference of the drum 22, and retains its shape and density, until the yarn is discharged from the drum 22 by a conveying device, not shown. It is only at this stage that what is referred to as the expansion of the strip takes place.
Major features of the nozzle 10 designed according to the invention, in conjunction with a drum 22, consist of the fact that the yarn strip, after leaving the compression part 16, is prevented from expansion. This is achieved in particular by the deflection between the first guide part 18 and the second guide part 20, as well as by the narrow guidance arrangement in these areas, for example between the second guide part 20 and a channel 24 in the perforated drum 22. With conventional nozzles, in which the textured yarn is laid freely on the surface of a cooling drum, the yarn strip can form loops due to the absence of lateral guidance, as a result of which a partial expansion of the strip takes place. Due to this free emergence of the yarn strip at the outlet of the nozzle, with the prior art as mentioned in the preamble, a more powerful braking effect is necessary in the area of the strip formation, i.e. in the compression part 16, in order to achieve the desired curling effect. This may lead to problems in the event of changes in the operational conditions, which have an influence on the friction coefficient.
Due to the fact that the strip is prevented from changing shape in or at the guide piece 18 and 20 respectively following the compression part 16, the texturing of the yarn in this part of the nozzle is better stabilized than with conventional nozzles.
According to
Attention may be drawn to the fact that the strip is indeed formed in the texturing nozzle 10, but its departure speed and packing density are not controlled in the nozzle, since it is only inadequately braked inside the nozzle channel, as a result of the weak friction of the strip inside the compression part 16, or the guide part 18 respectively. This is the result, therefore, of the fact that the cross-section of the channel in the compression part 16 or in the first guide piece 18 respectively, decreased comparatively sharply in the direction of the material flow, corresponding to a cone angle of 1 to 10 degrees, if the inner wall of the compression part 16 or of the guide part 18 respectively is designed in conical form.
As already mentioned, a precise and narrow position of a texturing nozzle 10 to the thread track concerned on the first drum 22 is necessary, since the departure speed and packing density of a strip is determined not in the texturing nozzle itself, but only at the circumference of the first drum. To draw the threads into the texturing system, the first drum 22 must be moved away from the nozzle block 100 or from the texturing nozzles 10 respectively, which is brought about to advantage by the pivoting or sliding of the drum 22 away from the nozzle block 100. It would likewise be possible for the nozzle block 100, or an individual texturing nozzle 10 respectively, to be moved away from the first drum 22 by means of a slide device. According to
Like the first drum 22, the second drum 23 also exhibits a drive unit 234 with bearing, whereby this can likewise exhibit an independent revolution-speed controlled electric motor.
As is shown in
According to
According to
The second and/or third, as appropriate, blower device respectively are designed arranged as in connection with the description of
According to
Expressed in general terms, the angle “a” between a first extension or projection line a′ at the outlet-side outer contour 28′ of a lamellar plate 28, and a second extension line b′ in an extension of a casing line of the circular truncated cone on the inlet side of the guide part 18, forms a first angle a, while the second extension line b′ encloses an angle b with an edge 10a of the nozzle 10. For preference, the following ranges are proposed for the angles a and b: a=0 . . . 1 . . . 4°, b=30 . . . 45 . . . 60°, whereby the values underlined have in practice transpired to be favourable. A separation plane 18″ may be located between the end piece 18′ and the first guide part 18.
In
According to
With a larger production system it may be of advantage to provide for an energy exchange arrangement for the cooling or heating of air by means of a cooling system 50. In the cooling system 50 is an inlet point 52a for ambient air, as well as a draw-off point 52b for cooled air, indicated in each case by dotted arrows. The cooling system comprises, for example, an evaporator 52 with a heat exchanger for a cooling medium, whereby, by the evaporation of the cooling medium, energy is drawn from the ambient air inflowing at 52a, whereby this air is cooled to the required degree and conducted onwards through the draw-off point 52b to the production system 40. In this situation, the energy drawn from the inflowing ambient air is conducted to the evaporator 52 per time unit E2 or per power unit, indicated by the arrow E2. In the circuit process for the cooling medium, this medium passes on the other side to a compressor 54 with heat exchanger for cooling the cooling medium which has been heating by the compression. In a further heat exchanger at the compressor 54, energy E1 is drawn off from the cooling medium, indicated by the arrow at E1, this energy being conducted to the ambient air introduced at the intake point 54a. This heated air, drawn off at the removal point 54b of the cooling system, can be used, for example, for heating the extruder 41, being conducted to this at the intake point 54c, or, for texturing at the texturing nozzles 10, at least for heating the air which is required at that location. The air which is cooled at the draw-off point 52b is, on the other hand, conducted in particular at the inlet point 52e to the cooling drums 22, 23, as shown in detail in connection with the figure description of
The energy E2 in the cooling circuit, conducted to the evaporator in the corresponding heat exchanger, is smaller per time unit or the corresponding power output, than the energy converted in the heat exchanger at the compressor 54, i.e. the energy introduced to the inflowing air, per time unit and per power unit E1. The difference corresponds to the power to be applied in the compressor 54 to the cooling medium in the cooling system 50.
It should be apparent to those skilled in the art that modifications and variations can be made to the embodiments of the invention described herein without departing from the scope and spirit of the appended claims and their equivalents.
Number | Date | Country | Kind |
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102 02 788.9 | Jan 2002 | DE | national |
The present application is a Divisional Application of U.S. application Ser. No. 11/216,994 filed on Aug. 31, 2005, which is a Divisional Application of U.S. application Ser. No. 10/349,485 filed on Jan. 22, 2003. Both U.S. application Ser. Nos. 10/349,485 and 11/216,994 are incorporated in their entirety by reference herein for all purposes.
Number | Date | Country | |
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Parent | 11216994 | Aug 2005 | US |
Child | 11581819 | Oct 2006 | US |
Parent | 10349485 | Jan 2003 | US |
Child | 11216994 | Aug 2005 | US |