The present application is a U.S. National Stage of International Application No. PCT/EP2014/064539, filed on Jul. 8, 2014, designating the United States and claiming the priority of European Patent Application No. 13177863.1 filed with the European Patent Office on Jul. 24, 2013. All of the aforementioned applications are incorporated herein in their respective entireties by this reference.
The invention relates to a circular weaving machine.
Circular weaving machines are generally known in which warp-tape guide elements, e.g., in the form of length adjustment compensators, are arranged around the circular reed of the circular weaving machine. Via those warp-tape guide elements or through them, a large number of warp tapes are supplied to the circular weaving machine in a circumferentially distributed fashion. From the warp-tape guide elements, the warp tapes run toward shed forming devices which comprise, for example, laces or bands provided with eyelets for passing through one warp tape at a time; subsequently, the warp tapes run through between bars of the circular reed. At the shed forming devices, the warp tapes are divided—in most cases in an alternating arrangement—into two warp-tape groups onto which mutually opposed alternating movements are imparted through an opposed movement of the laces or eyelet bands, with the result that the weaving shed (also referred to as a moving shed) is opened and closed. In the opened state, the weaving shed forms a space defined by the two warp-tape groups, in which a weaving shuttle carrying a weft-tape bobbin moves on an orbit along the circular reed and, in the process, draws off the weft tape from the weft-tape bobbin it carries, introducing it into the weaving shed. The size of the space of the weaving shed as defined by the two warp-tape groups changes constantly with the movement of the two warp-tape groups, starting from zero with a closed weaving shed in a position in which both warp-tape groups are located in the same surface, up to a maximum at which the two warp-tape groups are located at opposing reversal points of their alternating movement. At those reversal points, the so-called shed change starts by reversing the movement imparted to the opposed warp-tape groups, whereby the last introduced weft tape is fixed in the fabric and the next weft tape can be introduced into the weaving shed by the next shuttle. Usually, several weaving shuttles circulate in the circular reed at equal distances from each other. The produced tubular fabric is guided inwards toward a centrally arranged weaving ring, where it is deflected toward drawing-off rolls.
Such a circular weaving machine is known, for example, from EP 0 786 026 B1.
There has always been the need to enhance the performance of circular weaving machines. The overall performance of the circular weaving machine is significantly influenced by the so-called weft count, which is the number of weft tapes which can be introduced into the weaving shed per unit of time. The weft count is usually indicated in “picks per minute”. In the past, the weft count was increased by increasing the rotational speed of the shuttles in the circular reed and/or by increasing the number of shuttles. For example, in EP0167831A1, an increase in the rotational speed has been achieved by specifically designing the tracks on which the pairs of supporting rolls of the weaving shuttles run in the reed. Those specifically designed tracks have increased the smoothness of running of the weaving shuttles, resulting in less wear of the reed, thus allowing a higher rotational speed.
In the meantime, however, the performance limits of circular weaving machines have been reached, with the limiting factor being especially the resilience of structural elements upon which the centrifugal force of the weaving shuttles acts. In particular the guide elements on which the weaving shuttles run along the reed are strained and worn by the centrifugal force of the rotating weaving shuttles. The centrifugal force depends primarily on the mass of the weaving shuttles, the rotational speed (or the number of revolutions, respectively) and the reed's radius. With each increase in individual parameters, the centrifugal force and thus the strain and wear of the structural elements is increased.
Although the load capacity of structural elements onto which the centrifugal force acts is seemingly exhausted by the increase in the number of shuttles and in the speed of the main shaft driving the shuttles as well as the reduction in the weaving shuttle mass, an increase in the weft count of circular weaving machines is still endeavoured in the industry.
It is thus the object of the invention to increase the weft count of circular weaving machines without increasing the strain and wear of the structural elements as a result of the centrifugal force exerted by the rotating weaving shuttles, but, on the contrary, even with a decrease thereof.
The present invention achieves this objective by providing a circular weaving machine having the features of claim 1. Preferred embodiments of the invention are described in the subclaims.
The circular weaving machine according to the invention comprises:
With the loom in operation, the surface which contains the geometric connecting lines between the warp-tape guide elements and the weaving ring corresponds to the surface which is formed jointly by the two warp-tape groups if the weaving shed is closed. Furthermore, in a preferred arrangement of the warp-tape guide elements, the geometric connecting lines are arranged radially between the warp-tape guide elements and the weaving ring.
In comparison to conventional circular weaving machines in which the bobbin axis of the weft-tape bobbin is kept essentially horizontal by the weaving shuttle, the overall length of the weaving shuttle and hence its mass can be reduced by arranging the bobbin axis of the weft-tape bobbin, according to the invention, at an angular position which deviates by at most +/−15°, preferably at most +/−10°, from a normal to the surface of the closed weaving shed, which in turn allows a larger number of weaving shuttles to be provided, with the reed radius being the same. The larger number of weaving shuttles allows a reduction in the rotational speed of the shuttles, whereby, in total, the weft count of the circular weaving machine is increased over the prior art, without the (centrifugal) forces acting on the structural elements strained by centrifugal forces, such as shuttle rolls, circular reed etc., being increased.
An optimization of the above-mentioned advantages of the circular weaving machine according to the invention over conventional circular weaving machines is achieved if the weaving shuttle keeps the bobbin axis of the weft-tape bobbin essentially at right angles to the surface containing the geometric connecting lines between the warp-tape guide elements and the weaving ring.
In one embodiment of the circular weaving machine according to the invention, said surface forms essentially a circular ring surface.
In an alternative embodiment of the circular weaving machine according to the invention, said surface forms essentially a truncated cone surface the axis of which is the machine axis.
In order to be able to guide a weft-tape bobbin through the weaving shed in such a way that, at an angular position which deviates by at most +/−15°, preferably at most +/−10°, from a normal to the surface containing the geometric connecting lines between the warp-tape guide elements and the weaving ring, the bobbin axis thereof is most preferably essentially orthogonal to said surface, a suitable bobbin form has to be chosen. In comparison to weft-tape bobbin of the same total tape length, which are used in conventional circular weaving machines, it is suggested that the bobbin length (frequently also referred to as the traverse width) is reduced in the weft-tape bobbin intended for use in the circular weaving machine according to the invention and the bobbin diameter is increased. A weft-tape bobbin is recommended in which, in the full state, the bobbin diameter is larger than the bobbin length, whereby the available space in the weaving shed can be utilized optimally. Because of this bobbin form according to the invention, the mass of the bobbin is reduced and an additional reduction in the weaving shuttle mass (dead weight, empty weight) is achieved. The respective weight reductions of the bobbin and of the weaving shuttle result in a significant reduction in the centrifugal force acting on the structural elements during the rotation of the weaving shuttles.
Due to the suggested bobbin form, it is possible to reduce the required shed travel (the distance between the reversal points of the two warp-tape groups) and to decrease the transverse acceleration of the warp tapes during the shed change, resulting in a reduced strain on the weaving-shed forming devices.
Furthermore, the compensation distance of warp-tape length adjustment compensators between an opened and a closed weaving shed is reduced due to the shorter shed travel, whereby the differences in the tape tensions acting on the warp tapes between the opened and the closed weaving shed of the warp tapes are reduced and thus the strain on the warp tapes and the compensators is reduced as well.
The invention is now illustrated in further detail on the basis of exemplary embodiments with reference to the drawings. In the drawings:
For the sake of better clarity,
Between the warp-tape guide elements 2 and the circular reed 4, shed forming devices 5 are arranged around the circular reed 4 in a distributed fashion. The shed forming devices 5 comprise a plurality of first laces 6 and a plurality of second laces 7, which are interconnected at their ends and entwine an upper roll 8a as well as a lower roll 8b. Each of the first laces 6 has an eyelet 6a through which a warp tape 3 is guided. Said warp tapes passed through the eyelets 6a of the first laces 6 form a first warp-tape group 10. Each of the second laces 7 has an eyelet 7a through which a warp tape 3 is guided. Said warp tapes passed through the eyelets 7a of the second laces 7 form a second warp-tape group 11. At least one of the upper roll 8a and/or the lower roll 8b is rotated alternately into a first and an opposite second direction of rotation, whereby the laces 6, 7 entwining them are moved upwards and downwards in an alternating manner. As a result, a mutually opposed upward and, respectively, downward alternating movement is imparted to the two warp-tape groups 10, 11, with the result that the weaving shed 9 (also referred to as a moving shed) is opened and closed. In the opened state, the weaving shed 9 forms a space defined by the two warp-tape groups 10, 11, in which a weaving shuttle 12 carrying a weft-tape bobbin 13 moves on an orbit along the circular reed 4 and, in the process, draws off a weft tape, which is not illustrated, from the weft-tape bobbin 13 it carries, introducing it into the weaving shed 9. The weaving shed 9 is closed if the laces 6, 7 are located in a central position in which the eyelets 6a, 7a of the first laces 6 and the second laces 7 are on the same level, whereby both warp-tape groups 10, 11 are located in the same surface 9a or, respectively, jointly span said surface 9a. In other words, the surface 9a of the closed weaving shed 9 is the angle bisector between the first warp-tape group 10, which, in
The size of the space of the weaving shed 9 as defined by the two warp-tape groups 10, 11 changes constantly with the opposing movement of the two warp-tape groups 10, 11, starting from zero with a closed weaving shed. The space of the weaving shed 9 reaches a maximum if the two warp-tape groups 10, 11 are located at the opposite reversal points of their opposing alternating movement, as illustrated in
According to the invention, the weaving shuttle 12 keeps the bobbin axis 13a of the weft-tape bobbin 13 at an angular position β which deviates by at most +/−15°, preferably at most +/−10°, from a normal to the surface 9a of the closed weaving shed 9, using a bobbin holding device 12b. In the embodiment of the circular weaving machine according to
The circular weaving machine 1 is designed for the use of plastic tapes as warp tapes and weft tapes, the plastic tapes being elongated for achieving a higher strength. In order that the advantages of the circular weaving machine according to the invention are brought to bear fully, a type of weft-tape bobbin is used which is modified in comparison to conventional weft-tape bobbin in that the bobbin length L is reduced and the bobbin diameter D is increased. In the full condition of the weft-tape bobbin 13, the bobbin diameter D thereof is larger than the bobbin length L, whereby the available space in the weaving shed 9 can be utilized optimally. Because of this bobbin form, the weaving shuttle 12 can be constructed shorter, resulting in a reduction in its mass. As with the recommended bobbin form, the bobbin core 13b can be shorter and thus lighter, also the weft-tape bobbin 13 is lighter. The respective weight reductions of the bobbin 13 and of the weaving shuttle 12 result in a significant reduction in the centrifugal force acting on the supporting rolls 12a, the circular reed 4 and other structural elements during the rotation of the weaving shuttles 12.
Due to the suggested bobbin form, it is possible to reduce the required shed travel, resulting in a shortening of the reed bars 4c. In contrast to longer reed bars, shorter reed bars 4c will produce less noise caused by vibrations of the bars. A further noise reduction can be achieved by reducing the number of revolutions and the lower rotational speed of the weaving shuttles 12. A further advantage of the new bobbin form, in comparison to long bobbin of small diameters, is the lesser volume loss via the bobbin core relative to the total volume of the bobbin.
Because of the higher weft count of the described circular weaving machine 1, a smaller number of looms are required for the same output of fabric, which reduces the required space at the manufacturing facilities.
The following table shows a comparison of relevant technical data of a conventional type FX circular weaving machine of the applicant to those of the circular weaving machine according to the invention.
Number | Date | Country | Kind |
---|---|---|---|
13177863 | Jul 2013 | EP | regional |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2014/064539 | 7/8/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/010889 | 1/29/2015 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
1947976 | Dickie | Feb 1934 | A |
3815643 | Haoya | Jun 1974 | A |
3875973 | Kallmeyer | Apr 1975 | A |
4355666 | Torii | Oct 1982 | A |
4424836 | Torii | Jan 1984 | A |
4432397 | Cacciapuoti | Feb 1984 | A |
4479517 | Plammer | Oct 1984 | A |
4619293 | Huemer | Oct 1986 | A |
4776371 | Schonberger | Oct 1988 | A |
4821778 | Zacek | Apr 1989 | A |
4977933 | Brais | Dec 1990 | A |
5099891 | Hiramatsu | Mar 1992 | A |
5293906 | Amin | Mar 1994 | A |
5787938 | Starlinger Huemer | Aug 1998 | A |
5826626 | Huemer | Oct 1998 | A |
7926517 | Horimoto | Apr 2011 | B2 |
8082761 | Wang | Dec 2011 | B2 |
20060162954 | Horimoto | Jul 2006 | A1 |
20090126823 | Yengkhom | May 2009 | A1 |
20110014403 | Wang | Jan 2011 | A1 |
20160160409 | Hehenberger | Jun 2016 | A1 |
Number | Date | Country |
---|---|---|
102817162 | Dec 2012 | CN |
0167831 | Jan 1986 | EP |
0786026 | Aug 1998 | EP |
2036813 | Jul 1980 | GB |
20010037753 | May 2001 | KR |
Entry |
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Written Opinion of PCT/EP2014/064539, filed Jul. 8, 2014. |
International Search Report of PCT/EP2014/064539, dated Sep. 16, 2014, filed Jul. 8, 2014. |
IPRP of PCT/EP2014/064539, dated Aug. 18, 2015, filed Jul. 8, 2014. |
IPRP of PCT/EP2014/064539, dated Jan. 28, 2016, filed Jul. 8, 2014. |
Number | Date | Country | |
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20160160409 A1 | Jun 2016 | US |