The invention relates to a circular comb for a comber having a basic body, which is fastened on a circular comb shaft in a rotationally locked manner and supports, on the outer circumference thereof, at least one comb clothing, the clothing tips of which form an outer enclosing circle. A guide element fastened on the circular comb is provided following—as viewed in the combing direction of the comb clothing—the basic body supporting the comb clothing. The guide element has at least two mutually adjacent guide surfaces, wherein the first guide surface, which adjoins the basic body, is arranged within the enclosing circle and with substantially consistent radial clearance from the enclosing circle, and the adjoining second guide surface forms an obtuse angle with the first guide surface.
Document CH-654 599 makes known an embodiment of a circular comb for a comber, wherein a part 27 (called a guide element) is installed following a comb clothing (a needle segment having comb needles) in order to narrow the gap between the circular comb and the lower nipper plate. In this connection, the circular comb is rotatably mounted within a suction channel, to which a vacuum is applied in order to suction out the extracted components. The purpose of the additionally installed guide element (part 27) is to prevent the end of the fibrous web, which has been fed back by the detaching rollers, from being lifted off the lower detaching roller by the suction airflow present in the suction channel before the piecing process takes place. Such a lifting of the end of the fibrous web before the joining of the extracted fiber tuft protruding from the nipper disrupts the downstream joining process (piecing process) and results in unclean and faulty splices (piecings). The solution proposed in CH-654 599 improves the previous embodiments in terms of disruptive suction airflows.
As is also found in the cited prior art, the additional guide element (part 27) can extend only around a certain rotation angle of the circular comb in order to prevent a collision with the lower nipper plate of the nipper unit, which pivots back and forth.
Due to the demand to operate the combers at continuously increasing nip rates, the requirements regarding the production of high quality piecings are also continuously increasing. That is, at high nip rates, unwanted airflows have an even greater effect on the piecing process. In addition, it is becoming increasingly difficult to hold the fed-back end of the fibrous web on the periphery of the lower detaching roller before the end of the extracted fiber tuft protruding from the nipper is placed onto the end of the fibrous web. Due to the higher rotational speeds of the rotating parts, such as the circular comb and the brush roller, and the faster movements of the remaining parts, such as, e.g., the nipper unit, the generated airflows also change in the region of the join between the nipper unit and the detaching rollers. That is, the known guide elements following the comb unit, in the current geometric shape, are no longer capable of controlling the airflows in the region of the join such that a non-disrupted joining (piecing) of the extracted fiber tuft end to the fed-back end of the fibrous web is ensured.
A problem addressed by the invention is therefore that of improving or optimizing and developing known guide elements on the circular comb such that these ensure the production of high-quality piecings on the comber also at high nip rates. Additional objects and advantages of the invention will be set forth in part in the following description, or may be obvious from the description, or may be learned through practice of the invention.
In order to solve this problem, it is proposed that the radial clearance of the first guide surface of the guide element from the enclosing circle is between 4-10 mm and the second guide surface forms an angle between 130°-170° with the first guide surface, wherein the rear end—as viewed in the combing direction of the comb clothing—of the second guide surface has a radial clearance between 8-18 mm from the enclosing circle of the comb clothing and the length of the second guide surface is at least twice as great as the length of the first guide surface, as viewed in the circumferential direction of the circular comb.
Due to this special geometry of the guide element, it is possible to control the airflows within the region between the nipper unit, the circular comb, and the detaching rollers such that the end of the fibrous web fed back for the subsequent piecing process is held on the periphery of the lower detaching roller, also at high nip rates, in order to place the extracted end of the fiber tuft exactly onto the end of the fibrous web.
Advantageously, it is proposed that the first guide surface has a length between 5-20 mm. It is therefore ensured that the guide element will not collide with the back-and-forth pivoting nipper and that a reduction of the gap between the lower nipper plate of the nipper and the guide element that is sufficient to control the airflows is still available.
It is also advantageous when the second guide surface has a length between 20-50 mm.
In addition, it is proposed that a radius between 5-15 mm is provided between the first and the second guide surface.
It is thereby ensured that the end of the fiber tuft emerging from the comb clothing can gently glide from the first guide surface onto the downstream second guide surface. By introducing a radius in this transition region, trailing edges for the air circulation are avoided, which can otherwise result in additional air turbulences.
Preferably, another embodiment is proposed, wherein a third guide surface adjoins the end of the second guide surface as viewed in the circumferential direction of the circular comb and forms an angle between 90°-120° with the second guide surface, and the end of the third guide surface points in the direction of the circular comb shaft.
In order to ensure that no trailing edges for the airflow occur, which can additionally generate air turbulences, it is also proposed that a gentle transition having a radius between 5-15 mm is provided between the second and the third guide surface.
In order to avoid acting too harshly upon the fibers of the fiber tuft presented for combing when these impact the comb clothing, another guide element is installed directly in front—as viewed in the combing direction—of the basic body supporting the comb clothing, said guide element having at least two mutually adjacent guide surfaces, wherein the first guide surface, which adjoins the basic body, is arranged within the enclosing circle and with a substantially consistent clearance between 4-10 mm from the enclosing circle and the adjoining second guide surface forms an obtuse angle between 130°-170° with the first guide surface, wherein the front end—as viewed in the combing direction of the comb clothing—of the second guide surface is located with a radial clearance between 8-18 mm from the enclosing circle of the comb clothing and the length of the second guide surface is at least twice as great as the length of the first guide surface, as viewed in the circumferential direction of the circular comb.
The length of the first guide surface can be between 5-20 mm. The length of the second guide surface can be between 20-50 mm.
By means of this additional guide element, which can have the same design as the guide element following the comb clothing, the fiber tuft is gently inserted into the comb segment, thereby causing less fiber damage.
It is also proposed that a third guide surface adjoins the end of the second guide surface of the circular comb, as viewed in the circumferential direction of the circular comb, and forms an angle between 90°-120° with the second guide surface, and the end of the third guide surface points in the direction of the circular comb shaft.
In order to avoid trailing edges for the airflow, it is also proposed that a radius between 5-15 mm be provided at the transition between the guide surfaces of the additional guide element.
The guide elements are preferably made from aluminum or a plastic. The use of fiber reinforced materials is therefore included.
The guide elements should be made substantially from material having a low specific weight so that the loads (e.g., centrifugal forces) acting on the circular comb can be held as low as possible.
The guide elements can be fastened on the circular comb in various manners, e.g., by means of screwing, bonding, welding, etc.
In order to prevent fibers from depositing on the particular guide element, the guide surfaces of the particular guide element have a surface to which fibers do not adhere. It is possible to provide the guide surfaces of the guide elements with coatings. These surfaces can therefore also be designed to have greater wear resistance.
In order to ensure simple production, the guide element is integrally connected to the basic body. As a result, the installation of the guide element on the circular comb is eliminated and transition edges, onto which fibers can deposit, are avoided.
Further advantages of the invention are described in greater detail and illustrated with reference to the following exemplary embodiments, in which:
Reference will now be made to embodiments of the invention, one or more examples of which are shown in the drawings. Each embodiment is provided by way of explanation of the invention, and not as a limitation of the invention. For example features illustrated or described as part of one embodiment can be combined with another embodiment to yield still another embodiment. It is intended that the present invention include these and other modifications and variations to the embodiments described herein.
In order to reduce the clearance between the lower nipper plate 6 and the circular comb R in a certain rotation-angle position of the circular comb, a guide element 7 is installed following the basic body 18, the guide element extending across nearly the entire width B (see
Such a guide element, as shown in
The nipper unit is formed by a nipper frame 5, on which a lower nipper plate 6 is fastened. An upper nipper plate 2 is mounted on the nipper frame 5 so as to be pivotable about a pivot axis 4 and pivoting arms 3. In the embodiment shown, the nipper unit 1 is closed, wherein the fiber tuft FB protruding from the clamping point of the nipper unit is captured and extracted by the clothing G. Non-illustrated loading means (e.g., springs) act on the pivoting arms 3, wherein said loading means control the pivoting movement of the upper nipper plate 2 and generate a necessary clamping force in the clamping point of the nipper unit 1. A feed roller 16 is also rotatably mounted in the nipper frame 5, above the lower nipper plate 6, the feed roller being driven in steps, e.g., by a non-illustrated ratchet drive. A lap W (or individual slivers), which is fed to the nipper unit 1, is fed to the clamping point of the nipper unit via this feed roller 16. After the fiber tuft FB has been extracted, the nipper unit 1 is pivoted in the direction of a downstream detaching roller pair AW. In this pivoting process, the nipper unit opens and the extracted end of the lap W or the fiber tuft FB is placed onto the end E of a previously formed fibrous web V and is pieced therewith by means of the effect of the clamping point of the detaching rollers AW, and is carried off in the conveyance direction F.
Located between a support surface of the support element 13 and a base surface of the recess 24 is a replaceable spacer element D, by means of which the radius HR of the enclosing circle HK of the comb clothing G can be set or changed relative to the axle of the circular comb shaft 15. The objective is to set the clearance c (
The trough 21, or the recess 24, is located on an inner section 22 of the basic body 20, on which an outer section 23 is supported via the ribs. Hollow spaces are formed between the ribs and the inner and the outer section 22, 23.
In order to fasten the basic body 20 with the support element 13 and a balancing element AG1 on the circular comb shaft 15, the shaft is provided with a plurality—as viewed along the width B of the circular comb R—of passage holes, through which screws S3 extend. The head of the particular screw S3 is located in a recess of the balancing element AG1. In addition, a passage hole, which is aligned with the bore of the circular comb shaft 15, is provided in the balancing element AG1. The support element 13, the spacer element D, and the basic body 20 are provided with passage holes, which are aligned with the bores of the circular comb shaft 15 and through which the particular screw S3 extends. The end of the particular screw S3 has a thread, which extends beyond the bore of the basic body 20 in the region of a hollow space. A nut 46 is installed on the thread. By tightening the screws S3 and screwing these into the threaded bore of the nut, the basic body 20 with the support element 13 and the balancing element AG1 are pressed against one another and are fixedly clamped on the shaft 15 and are fixed in position.
Additional details of this fastening and of the design of the basic body as a hollow profile can be found, e.g., in the published document CH-707882.
As also shown in
In the present example, the guide means 7a has a first guide surface f1, which can have a length l1 of 5 to 20 mm. The guide surface f1 extends with an approximately parallel clearance e of 4 to 10 mm from the outer enclosing circle HK of the comb clothing G. The first guide surface f1 adjoins a subsequent, second guide surface f2 so as to form an obtuse angle α between 130° and 160°. A radius r1 of 5 to 15 mm is provided at the transition between the first and the second guide surface. As a result, a gentle transition is created and a trailing edge is avoided, which can result in air vortices under certain circumstances. The end H of the second guide surface has a radial clearance M from the enclosing circle HK between 8 and 18 mm. It is thereby ensured that a constriction of the air passage that is sufficient to control the airflows is still available underneath the lower nipper plate, also over the rear region of the guide element 7a, wherein a collision of the guide element with the lower nipper plate is ruled out.
A third guide surface f3 is provided following the second guide surface f2 and forms an angle 3 between 90° and 120° with the second guide surface f2. The third guide surface f3 (f3′) leads into the base surface GF (GF′) of the guide element 7a (7b). A radius r2 of 5 to 15 mm is provided at the transition from the second guide surface f2 to the third guide surface f3 for the reasons described above. As the schematic view X according to
One possible installation of another guide element 7b is shown as a dash-dotted depiction, said guide element being installed in front—as viewed in the comb direction L—of the comb clothing G or in front of the outer section 23 of the basic body 20. The outer shape of the guide element 7b corresponds to that of the guide element 7a described above and is fastened on a connecting piece R1 of the basic body 20 on the opposite side, as a mirror image. The guide element 7b also has three guide surfaces f1′ to f3′, which extend toward one another at the angles α and β described above. The length l1′ of the first guide surface f1′ can also be between 5 and 20 mm, whereas the length l2′ of the second guide surface f2 can be 20 to 50 mm. Radii r1 and r2 are also provided at the transitions between the guide surfaces f1′-f3′ for the reasons described above.
The clearance e′ between the enclosing circle HK and the first guide surface f1′ is between 4 and 10 mm, whereas the radial clearance M between the end H′ of the second guide surface f2′ and the enclosing circle HK is between 8 and 18 mm. The guide element 7b can be fastened on the basic body 20 similar to the fastening of the guide element 7a described above.
By means of the additionally installed second guide element 7b having the correspondingly arranged guide surfaces f2′ and f1′, the end of the fiber tuft FB is already oriented and prepared for entry into the comb segment G such that an abrupt deflection of the fiber tuft upon entry into the comb clothing is avoided.
Fiber damage can be avoided as a result. The use of the additional guide element also has advantageous effects in terms of a controlled airflow in the region between the nipper and the detaching rollers AW.
Modifications and variations can be made to the embodiments illustrated or described herein without departing from the scope and spirit of the invention as set forth in the appended claims.
Number | Date | Country | Kind |
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01987/14 | Dec 2014 | CH | national |
Number | Name | Date | Kind |
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5038440 | Demuth | Aug 1991 | A |
5657512 | Graf | Aug 1997 | A |
6353974 | Graf | Mar 2002 | B1 |
20130263408 | Muller | Oct 2013 | A1 |
20150167203 | Shimbara | Jun 2015 | A1 |
Number | Date | Country |
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654 599 | Feb 1986 | CH |
707 882 | Oct 2014 | CH |
2426239 | Mar 2012 | EP |
2789716 | Oct 2014 | EP |
WO 2012027852 | Mar 2012 | WO |
Number | Date | Country | |
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20160177477 A1 | Jun 2016 | US |