The present invention relates to an apparatus for wetting an advancing filament bundle which is capable of closely controlling the amount of the fluid applied to the bundle.
In the production of synthetic multifilament yarns or synthetic multifilament tows, it is known to apply a fluid to the filament bundle forming the yarn or tow for purposes of forming a yarn coherence, or enabling further processing, or effecting a cooling. In this process, the fluid may be applied by a nozzle, which generates a spray jet that is directed toward the filament bundle, as is disclosed, for example, in EP 0 344 649. Methods and apparatus of this type have been found satisfactory in particular for a continuous wetting of a filament bundle.
To wet a filament bundle at a varied speed of advance with different applications of fluid, nozzles of the described type are however suited only to a limited extent. For example, a reduction of the fluid quantity that is sprayed on by the nozzle, directly leads to a change in the spray pattern or spray angle. Thus, it is possible only to a limited extent to influence the fluid application to the filament bundle by controlling the nozzle. The known method and the known device are unable to perform a fine adjustment of the fluid applications to the filament bundle.
It is therefore an object of the invention to further develop an apparatus for wetting an advancing filament bundle in such a manner that the filament bundle is able to receive at a speed of advance an adjustable and substantially constant application of fluid.
The above and other objects and advantages are achieved by the present invention which has the advantage that regardless of the respectively desired fluid application to the filament bundle, it is always possible to operate the nozzle in an optimal work range with a constantly delivered quantity of fluid. The spray jet generated by the nozzle is constant in its dimensions. To adjust the fluid application, the invention provides for shielding a portion of the spray jet before impacting upon the filament bundle, so that only the unshielded portion of the spray jet is effective for wetting the filament bundle. The application of fluid to the filament bundle is thus defined by the degree of shielding of the spray jet. A high degree of shielding of the spray jet effects a relatively small fluid application, and a small degree of shielding a large fluid application to the filament bundle.
To wet the filament bundle with a constant and uniform application of fluid even at a varied speed of advance, an advantageous further development of the invention provides for varying the degree of the shielding of the spray jet. With that, it is possible to adapt the application of fluid always to the process or process changes.
In this connection, it is especially advantageous to adapt the application of fluid constantly to the speed of advance of the filament bundle. To produce a constant application of fluid to the filament bundle, the degree of shielding is lessened, when increasing the speed of advance of the filament bundle, in such a manner that the portion of the spray jet impacting upon the filament bundle becomes greater and, thus, the fluid application remains constant even at a higher speed of advance.
To vary the degree of the shielding of the spray jet, it is possible to make either the shielding means arranged between the nozzle and the filament bundle movable, or to construct the nozzle for movement, so that the shielding means covers a more or less defined portion of the spray jet.
Since in the case of relatively small fluid applications to the filament bundle, a considerable portion of the spray jet is not used for wetting the filament bundle, it is preferred to use the further development of the invention, wherein the fluid of the shielded portion of the spray jet is collected, drained, and delivered into a tank. To this extent, it is advantageous to construct the shielding means as a drip plate, with the collected fluid being discharged via a drain into the spray box.
The collection and discharge of the unused fluid enables another, especially preferred further development of the invention, wherein the drained fluid is measured to determine an actual quantity of the fluid application directly from the difference between the quantity of fluid delivered through the nozzle and the drained quantity of fluid. With that, it is possible to determine the actual application of fluid to the filament bundle.
To this end, the device of the invention comprises a measuring unit, which is used to determine on the one hand the quantity of fluid that is returned via a return flow line into the tank, and on the other hand the quantity of fluid that is delivered from the source of fluid to the nozzle. The measuring unit connects to a control unit, in which the actual fluid application can be computed by subtraction.
To obtain a constant application of fluid at any time irrespective of the speed of advance of the advancing filament bundle, an especially preferred further development of the invention provides for adjusting the degree of shielding as a function of a comparison between actual and desired values of the fluid application. To this end, a defined signal is generated within the control unit as a function of the comparison between actual and desired quantities. This signal is used to control the movement of the shielding means or the actuator that performs the movement of the nozzle.
To obtain a uniform wetting even in the case of very thick filament bundles, which are produced, for example, in the production of tows, it is advantageous to operate the device of the invention with two nozzles inside the spray box, with a shielding means being associated to each of the oppositely arranged nozzles. With that, the filament bundle is simultaneously wetted from an upper side and an underside.
In the following, the method and apparatus of the invention are described in greater detail by means of some embodiments of the device according to the invention with reference to the attached Figures, in which:
Inside the spray box 1, a nozzle 6 is arranged in spaced relationship with the guide path defined by the filament bundle 5. To this end, the nozzle 6 is mounted to a support 7 inside the spray box 1 in such a manner that a spray jet 11 generated by the nozzle 6 can be produced in the direction of the filament bundle 5. The nozzle 6 is constructed for pivotal movement on the support 7. The pivotal movement of the nozzle 6 is performed by an actuator 12 that is constructed as a pivot drive. The pivot drive 12 connects to a control unit 20.
Via a supply line 13, the nozzle 6 connects to a source of fluid 14. The source of fluid 14 is formed by a pump 15 and a motor 16 that drives the pump 15. The pump 15 connects via a suction line 29 to a tank 17. The tank 17 holds a fluid 21.
Inside the spray box 1 a shielding means 8 is arranged between the filament bundle 5 and the nozzle 6. The shielding means 8 is constructed as a drip plate 9, which is rigidly connected to the spray box 1. In this arrangement, the drip plate 9 totally covers the filament bundle 5 in the region of the spray jet 11. Depending on the position of the nozzle 6, only a portion of the spray jet 11 is collected by the drip plate 9. The drip plate 9 has a drain 10, which guides the collected fluid within the spray box 1 to a discharge opening 4. Connected to the discharge opening 4 in the bottom region of the spray box 1 is a return flow line 18, which connects the spray box 1 with the tank 17.
The control unit 20 is coupled with a sensor 22, which signals the momentary speed of advance of the filament bundle 5 to the control unit 20.
In the embodiment shown in
In the case that the speed of advance vF of the filament bundle slows down, a corresponding signal is supplied via the sensor 22 to the control unit 20. The control unit 20 will then transmit a control signal to the pivot drive 12, so that the nozzle 6 is pivoted by the pivot drive in the direction of the drip plate 9. This situation is shown in phantom lines in
The embodiment of
The fluid that is shielded and collected by the drip plates 25 and 26 is guided via its respective drain 10 to the discharge opening 4 of the spray box 1, with the discharge opening 4 connecting via the return flow line 18 to the tank 17.
Outside the spray box 1, a measuring unit 19 is provided, which connects on the one hand to the supply line 13 of the pump 15, and on the other hand to the return flow line 18. With the use of flow sensors, the measuring unit 19 determines the fluid quantities in the supply line 13 and the return flow line 18. The measuring unit 19 connects to the control unit 20.
In the device shown in
To determine the fluid application to the filament bundle 5, the total fluid quantity QG delivered by the pump 15 is determined by the measuring unit 19. Likewise, the fluid quantity QR that is discharged through the return flow line 18 into the tank 17 is measured. From the two measured values, it is possible to compute by subtraction the usable fluid quantity QN that defines the fluid application. Accordingly, QN=QG−QR.
In the control unit 20, the actual and desired values of the computed usable fluid quantity QN are compared. In the case of a deviation, the control unit 20 generates a control signal and supplies it to the actuator 28. The actuator 28 performs a corresponding position change of the holder 27 and thus changes the position of the upper drip plate 25 and the lower drip plate 26. Thus, the degree of overlap of the spray jet 11 will increase, for example, when a predetermined desired value of the usable fluid quantity QN is exceeded. With that, less fluid would reach the filament bundle 5. In the case that the desired value is not reached, the degree of overlap of the spray jet 11 is reduced, so that the holder 27 is moved by the actuation drive 28 in the direction of the inlet 2. It is thus possible to produce a uniform and constant fluid application irrespective of the state and the advance of the filament bundle 5. The nozzles 6 and 23 operate in this process under constant conditions. The spray pattern of the spray jet 11 that is generated by the nozzles 6 and 23, is preferably rectangular.
Both the method and the apparatus of the invention are suitable for applying to the filament bundle for its lubrication, for example, a yarn lubricant, which may consist, for example, of an oil-water emulsion. However, it is also possible to apply to the filament bundle any desired fluids, such as, for example, pure water for cooling or conditioning. The method and the device of the invention can be used regardless of whether the filament bundle is a single synthetic yarn or a tow formed by a yarn bundle.
Many modifications and other embodiments of the inventions set forth herein will come to mind to one skilled in the art to which these inventions pertain having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is to be understood that the inventions are not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.
Number | Date | Country | Kind |
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102 05 005 | Feb 2002 | DE | national |
The present application is a division of U.S. application Ser. No. 10/912,634 filed Aug. 5, 2004 now U.S. Pat. No. 7,157,122, which in turn is a continuation of international application PCT/EP2003/000941, filed 30 Jan. 2003, and which designates the U.S. The disclosures of the referenced applications are incorporated herein by reference.
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Number | Date | Country |
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0 344 649 | Dec 1989 | EP |
0 965 673 | Dec 1999 | EP |
2 479 290 | Oct 1981 | FR |
Number | Date | Country | |
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20060188594 A1 | Aug 2006 | US |
Number | Date | Country | |
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Parent | 10912634 | Aug 2004 | US |
Child | 11406146 | US |
Number | Date | Country | |
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Parent | PCT/EP03/00941 | Jan 2003 | US |
Child | 10912634 | US |