Abstract:
Liquid finish is applied to a travelling filament by bringing the travelling filament into contact with an arcuate surface portion associated with a normally stationary, but rotatable, annular finish applicator, and thereafter periodically rotating the annular finish applicator to bring at least one other arcuate surface portion thereof into contact with the travelling filament. Most preferably, an actuator assembly is provided having first and second actuator fingers which are capable of relative separable rectilinear movements towards and away from one another. These actuator fingers, in an especially preferred embodiment, are each pivotally moveable and magnetically coupled to one another. As such, separable movement will in turn cause that one of the actuator fingers connected to the annular finish applicator to pivot thereby rotating the later to expose a “fresh” arcuate surface region in contact with the filament.

Description:
FIELD OF THE INVENTION 
     The present invention relates generally to the field of synthetic filament production. More specifically, the present invention relates to the field of liquid finish applicators and methods whereby a liquid finish is applied onto surfaces of synthetic filaments. 
     BACKGROUND AND SUMMARY OF THE INVENTION 
     Synthetic filaments are traditionally produced by various spinning techniques. For example, synthetic filaments may be melt-spun by extruding a melt-spinnable polymer through relatively small-sized orifices in a spin pack to form a stream of filaments that is substantially immediately solidified in a quench cabinet. The filaments are thereafter continuously taken up by a high speed winder to form a generally cylindrical package. Depending on the intended end use, the filaments may be undrawn or may be subjected to a drawing step prior to being taken up to form the package. 
     The solidified filaments are typically passed through a metered finish applicator, which applies a liquid finish material (colloquially referred to as a “finish oil”) so as to lubricate the filaments to reduce filamentary friction and/or to achieve desired processability characteristics. Typically, a finish applicator mounting unit supports a plurality of fixed-position finish applicator nozzles that each include a slot to receive the individual filament threadlines. A portion of the slot against which the filaments are guided includes a small opening for the finish oil. Thus, as the filaments pass through the finish applicator nozzle during production, the finish oil is supplied to the slot and thereby coated onto the filaments. 
     The finish applicator nozzles are typically formed of a durable, low friction material, such as a ceramic material. Over time, however, the small amount of friction between the filaments moving at a relatively high speed and the stationary finish applicator nozzle causes some wear to be experienced in the latter. A greater amount of friction on the moving filaments will result as the finish applicator nozzle experiences greater wear which, in turn, is detrimental to the filaments. Too great a frictional force against the filaments can, in extreme cases, cause filament breakage requiring production down time. 
     Recently, U.S. Pat. No. 5,679,158 (the entire content of which is expressly incorporated hereinto by reference) suggested providing a finish applicator assembly with applicator nozzles removably received in a corresponding aperture of a mounting unit. While the applicator nozzles of this U.S. &#39;158 patent are more easily accessible for the purpose of cleaning, repair and/or replacement, some improvements are still desired. 
     For example, it would especially be desirable for finish applicators and methods to be provided which would increase the wearability of the finish applicator thereby lessening the friction experienced between the applicator and the moving filaments over a significantly greater period of time than can now be accomplished. It is towards fulfilling such a need that the present invention is directed. 
     Broadly, the present invention is embodied in apparatus and methods whereby a finish oil may be applied onto a moving filament by a stationary, yet periodically movable finish applicator. The finish applicator is most preferably annular and is thus capable of being rotated relative to the traveling filament so as to sequentially bring at least one and another arcuate applicator surface segments into contact with the travelling filament. By continually exposing different surface segments of the finish applicator to filament contact at different times, the amount of wear experienced by a single one of the surface portions is minimized. As such, the finish applicator is capable of being kept in production for prolonged time periods and thus minimizes (if not eliminates entirely) at least some of the problems noted previously with respect to conventional finish applicators. 
     Thus, in one especially preferred aspect of the present invention, liquid finish is applied to a travelling filament by bringing the travelling filament into contact with an arcuate surface portion associated with a normally stationary, but rotatable, annular finish applicator, and thereafter periodically rotating the annular finish applicator to bring at least one other arcuate surface portion thereof into contact with the travelling filament. Most preferably, an actuator assembly is provided having first and second actuator fingers which are capable of relative separable rectilinear movements towards and away from one another. These actuator fingers, in an especially preferred embodiment, are each pivotally moveable and magnetically coupled to one another. As such, separable movement will in turn cause that one of the actuator fingers connected to the annular finish applicator to pivot thereby rotating the later to expose a “fresh” arcuate surface region in contact with the filament. 
     These and other aspects and advantages will become more apparent after careful consideration is given to the following detailed description of the preferred exemplary embodiments thereof. 
    
    
     BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS 
     Reference will hereinafter be made to the accompanying drawings, wherein like reference numerals throughout the various FIGURES denote like structural elements, and wherein; 
     FIG. 1 is a schematic illustration of a melt spinning system in which the finish applicator assembly of the present invention may be employed; 
     FIGS. 2A through 2C are perspective views of a preferred embodiment of a finish applicator assembly of the present invention at different operational stages; and 
     FIGS. 3A through 3C are end elevational views of the finish applicator assembly at different operational stages corresponding to FIGS. 2A through 2C, respectively. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     In a typical melt spinning apparatus as shown in FIG. 1, an extruder  10  extrudes a polymer melt through a spin pack  12  having a plurality of spinneret orifices that form a plurality of filament threadlines  14 . It will be understood that, depending on the intended end use, each of the threadlines may include a single filament or may include any number of filaments forming a yarn. The filament threadlines  14  are first cooled in a quench cabinet  16  and may thereafter be drawn by a drawing assembly  22 , comprised of godet rolls  22   a - 22   c . The finished filaments are then wound by a high speed winder  24  to form a package  24   a . Prior to being taken up by the winder  24 , the filament threadlines  14  may be brought into contact with a finish applicator FA according to this invention so that finish oil may be applied. 
     As is more clearly depicted in accompanying FIGS. 2A-2C and  3 A- 3 C, the finish applicator FA includes a base frame  32  supporting opposed pairs of upright frame members  32 ,  34 . Upper and lower pairs of guide rods  36 ,  38  span the distance between, and are thus supported by, the upright frame members  32 ,  34 . Extending transversely between these guide rods  36 ,  38  are a finish applicator roll  40  and a filament guide roll  42 , each being mounted for rotational movement about its respective longitudinal axis. In this regard, cross-support members  44 ,  46  extend between the opposed pairs of upper and lower guide rods  36 ,  38  and are slidably coupled thereto by bushings  44 - 1  and  46 - 1  and slide blocks  44 - 2  and  44 - 2  at respective ends thereof. The rolls  40 ,  42  are carried by the transverse supports  44 ,  46  by means of one-way clutch bearings  40 - 1 ,  42 - 1 , respectively (see FIGS.  3 A- 3 C), the purpose of which will be explained in greater detail below. 
     A pair of actuator fingers  40 - 2 ,  42 - 2  are connected operatively to their respective clutch bearing  40 - 1 ,  42 - 1  and extend radially outwardly therefrom in a generally opposed direction relative to one another. Most preferably the actuator fingers  40 - 2  and  42 - 2  are magnetically attracted to one another so as to be magnetically coupled when in contact, the purpose of which will be explained in greater detail below. The bushings  44 - 1 ,  46 - 1  and slide blocks  44 - 2 ,  46 - 2  allow the cross-support members  44 ,  46  and the rolls  40 ,  42  carried thereby, to be moved reciprocally along the guide rods  36 ,  38 , respectively. The slide block  44 - 2  is most preferably positioned relative to the filament threadlines  14  during start-up and fixed in place (e.g., by clamping) to the guide rods  36 . Thereafter, in use, the slide block  44 - 2  (and thus roll  40 ) remains stationary while the slide block  46 - 2  is capable of being moved reciprocally along the guide rods  38  so as to move the roll  42  carried thereby towards and away from the roll  40 . 
     The rolls  40 ,  42  are provided with a series of annular finish applicator and guide slots (a representative few of which are identified in FIGS. 2A-2C by reference numerals  40 - 3 ,  42 - 3 , respectively) which are spaced apart from one another along the longitudinal axis of the rolls  40 ,  42 . Each of the annular applicator and guide slots  40 - 3 ,  42 - 3 , respectively, is most preferably formed of a ceramic material so as to minimize friction against the travelling filaments in contact therewith. A series of finish applicator nozzles  48  are removably supported by the cross-support member  44  so as to be in registry with a respective one of the annular applicator slots  40 - 3 . The applicator nozzles  48  are fluid-connected to a source of liquid finish (not shown) so that the liquid finish material may be supplied to, and discharged from, the nozzles  48  onto each respective annular applicator slot  40 - 3 . Filament strands  14  in contact with the annular applicator slots  40 - 3  will thus be coated with the liquid finish supplied thereto by means of the nozzles  48 . A drain tray  50  is positioned below the annular applicator slots  40 - 3  so as to receive excess liquid finish. 
     In use, filament threadlines  14  will be positioned in contact around a forward surface portion of a respective annular applicator slot  40 - 3  and a rearward surface portion of a respective annular guide slot  42 - 3 . The individual filament strands  14  will thus be in contact along a selected arcuate segment (known as the “wrap angle”) of the annular and  25  applicator slots  40 - 3 ,  42 - 3 . This wrap angle may, however, be changed by reversing the stop arm  52  which depends from, and is carried by, the cross-support  44 . That is, as is perhaps more clearly shown in FIGS. 3A-3B, a stop  54  carried by the slide block  46 - 2  is normally in contact with the lower end of the stop arm  52 . If the stop arm  52  is reversed, the larger boss at the terminal end  52 - 1  thereof will thus be in contact with the stop  54  thereby increasing the horizontal separation distance between the rolls  40 ,  42  (and thereby decreasing the wrap angle of the filaments around the annular applicator and guide slots  40 - 3 ,  42 - 3 , respectively). Most preferably, the stop  54  is magnetized so as to be magnetically coupled to the stop arm  52  when in contact therewith. Magnetic coupling between the stop  52  and stop arm  54  will thus maintain the rolls  40 ,  42  (and the actuator fingers  40 - 2 ,  42 - 2 ) in their normal operative positions as depicted in FIGS. 2A and 3A during the filament spinning operation. 
     Periodically in the filament production cycle, there is a need to doff the yarn packages  24   a . During such time, the threadlines will be directed “off-line” prior to restringing onto a fresh yarn package core. At this time, an operator will separate the rolls  40  and  42  in a horizontal dimension by sliding the slide block  46 - 2  rectilinearly along the guide rods  38  in the direction of arrow A 1  (see FIGS.  3 B and  3 C). The roll  42  will thus move away from roll  40  thereby increasing the horizontal separation distance therebetween. Each of the actuator fingers  40 - 2 ,  42 - 2  will, in response to such rectilinear movement of the slide block  46 - 2 , rotate in the directions of arrows A 2  and A 3  (see FIG.  3 B), respectively, due to the magnetic coupling therebetween. 
     As noted previously, the actuator fingers  40 - 2 ,  42 - 2  are connected operatively to one-way clutch bearings  40 - 1 ,  42 - 1 , respectively. Thus, when the actuator fingers  40 - 2 ,  42 - 2  are rotated in the directions of arrows A 2  and A 3 , the one-way clutch bearings  40 - 1 ,  42 - 1  will responsively “free-wheel”. As a result, the rolls  40 ,  42  will not rotate in response to rotation of the actuator fingers  40 - 2 ,  42 - 2  in the direction of arrows A 2  and A 3 . In other words, the one-way clutch bearings  40 - 1 ,  40 - 2  will cause the rolls  40 ,  42  to rotate only in response to rotation of the actuator fingers  40 - 2 ,  42 - 2  in a direction opposite to arrows A 2  and A 3  as will be explained in greater detail below. 
     Continued movement of the slide block  46 - 2  (i.e., in the direction of arrow A 1  from the state depicted in FIGS. 2B and 3B) will thus cause the actuator fingers  40 - 2 ,  42 - 2  to physically separate from one another as depicted in FIGS. 2C and 3C. In such a state, the threadlines  14  may be more easily re-strung. 
     Following re-stringing of the filament threadlines  14 , the slide block  46 - 2  may be rectilinearly moved along guide rod  38  toward roll  40  (i.e., in a direction opposite to arrow A 1  in FIGS.  3 B and  3 C). The actuator fingers  40 - 2 ,  42 - 2  will thus again be brought into contact with one another as shown in FIG.  3 B. As a result of continued movement of the slide block  46 - 2  in a direction opposite to arrow A 1 , the actuator fingers  40 - 2 ,  42 - 2  to be rotated in a direction opposite to arrows A 2  and A 3 , respectively. However, rotation of the actuator fingers  40 - 2  and  42 - 2  in directions opposite to arrows A 2  and A 3 , respectively, will cause the rolls  40 ,  42  to be driven in the same rotational direction by virtue of the interconnection of the fingers  40 - 2 ,  42 - 2  with their respective one-way clutch bearing  40 - 1 ,  42 - 1 . The surfaces of the annular applicator and guide slots  40 - 3 ,  42 - 3  which are exposed to the filament strands  14  upon subsequent re-stringing will thus be changed. As a result, fresh surfaces of the annular applicator and guide slots  40 - 3 ,  42 - 3  will be presented to the threadlines  14 . 
     It will be understood that the description of the rotation of the rolls  40 ,  42  (and hence the annular applicator and guide slots  40 - 3 ,  42 - 3  carried thereby) as being rotated only when the actuator fingers  40 - 2 ,.  42 - 2  are rectilinearly advanced toward one another represents a presently preferred embodiment of the present invention. Thus, it is entirely possible in accordance with the present invention that the rolls  40 ,  42  (and hence the annular applicator and guide slots  40 - 3 ,  42 - 3  carried thereby) may be rotated during relative rectilinear separation of the actuator fingers  40 - 2 ,  42 - 2 , depending on the operation of the one-way clutch bearings  401  and  42 - 1 , respectively. Furthermore, if desired, the magnetic coupling of the actuator fingers could be employed in the absence of a one-way clutch bearing to cause rotation of the rolls  40 ,  42  (and hence the annular applicator and guide slots  40 - 3 ,  42 - 3  carried thereby) in response to the actuator fingers  40 - 2 ,  42 - 2  being rectilinearly advanced and retracted relative to one another. Suffice it to say here, therefore, that one skilled in this art may recognize that a variety of substantially equivalent structures may be provided to achieve substantially the same result in substantially the same way as described above. 
     Furthermore, although one-way clutch bearings have been described in detail above, it will be understood that they also presently represent the most preferred embodiment of the invention. Thus, a variety of equivalent arrangements to achieve one-way roll rotation can be envisioned, such as, for example, a pawl and ratchet assembly, cooperating rollers, rack and pinion systems, torsional spring systems and the like. Furthermore, it will be understood that the guide roll  42 , although presently preferred, is not absolutely necessary in order to impart a liquid finish to filament surfaces. Thus, only the roll  40  may be provided in a finish applicator in accordance with the present invention, in which case, the actuator finger  40 - 2  may be contacted by a rotational or stationary magnetic finger member associated with a slide-block actuator or by any of the equivalent means noted above. 
     Therefore, while the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.