The present disclosure relates to a guide device comprising a guide with one or more guide elements for guiding a rapier bar in a rapier weaving machine, wherein this guide device is provided with an air circuit through which compressed air can flow and which is provided with perforations for cooling the rapier bar by means of compressed air.
In addition, the present disclosure relates to an assembly of a rapier bar, drive means for driving this rapier bar and such a guide device.
Furthermore, the present disclosure relates to a rapier weaving machine comprising such an assembly.
Rapier weaving machines comprise one or more rapiers for introducing weft yarns in a shed between warp yarns in order to form a fabric. In this case, the rapiers take the weft yarns to transfer means which may, for example, consist of a second rapier. In order to be able to receive the weft yarns in a reliable manner, the rapiers have to be accurately positioned during this transfer. These rapiers are fitted to rapier bars and are moved through the shed by means of this rapier bar in the rapier weaving machine. The movement of this rapier bar is in this case guided by means of one or more guide elements in order to be able to accurately position the rapier bar.
Such one or more guide elements together form a guide for this rapier bar. Such a guide is provided for each rapier in a rapier weaving machine. This guide is accommodated in a guide device which in addition also comprises a support structure for this guide. In a rapier weaving machine in which several rapiers are introduced in the shed on the same side of the fabric, such a guide device may comprise for each rapier such a guide with one or more guide elements or a guide device with such a guide with one or more guide elements may be provided for each rapier. The one or more guide elements which form the guide, are the parts of such a guide device which are arranged adjacent to the movement trajectory of the rapier bar and may come into contact with this rapier bar when the rapier bar is moved. In this case, these one or more guide elements delimit the movement trajectory of the rapier bar in one or more directions at right angles to this movement trajectory.
Various kinds of such guide elements are known. In the past, such guide elements often consisted of guide rollers.
However, when guiding the rapier bar, this rapier bar heats up due to the friction with the guide elements. When a rapier bar is guided using guide rollers, it is difficult to limit the heating up of such a rapier bar. EP 0 866 156 B1 therefore proposes to provide a fixedly arranged guide element with an air circuit through which compressed air can flow and which is provided with perforations for mounting and cooling the rapier bar using compressed air. In this case, the perforations are provided in a plane of the rapier element which faces the rapier bar when guiding this rapier bar.
However, at increased weaving speeds, cooling guide elements using compressed air as described in EP 0 866 156 B1 no longer suffices.
In order to be able to make them more lightweight yet still strong, more recent rapier bars are typically also made from materials which are less well able to conduct heat, as a result of which there is a greater need to cool these rapier bars.
It is the object of the present disclosure to provide a guide element by means of which a rapier bar may be guided sufficiently and by means of which it is possible to ensure cooling of the rapier bar more satisfactorily, even at relatively high weaving speeds.
This object of the disclosure is achieved by providing a guide device comprising a guide with one or more guide elements for guiding a rapier bar in a rapier weaving machine, wherein this guide device is provided with an air circuit through which compressed air can flow and which is provided with perforations for cooling the rapier bar using compressed air, and wherein this guide device is provided with a cooling circuit through which coolant can flow for cooling the rapier bar using coolant.
By means of a combination of both cooling by means of compressed air and cooling by means of a coolant, it is possible to sufficiently limit warming up of this rapier bar by friction even at relatively high weaving speeds. The rapier bar may be guided sufficiently to ensure more accurate positioning of the rapier and be cooled sufficiently to reduce warming up thereof.
The perforations for passing through compressed air in order to cool down the rapier bar are preferably provided in the guide. Preferably, these perforations are in this case provided in a surface which faces the rapier bar when guiding the rapier bar, as is the case in the prior art.
Preferably, the guide extends along a longitudinal direction for guiding the rapier bar and the guide device comprises at least one air-guiding zone, in which the perforations are arranged, wherein this air-guiding zone is provided in the guide and, viewed in the longitudinal direction, extends along a smaller length than this guide.
By limiting the air cooling to one or more discrete air-guiding zones, it is possible to reduce the cost for cooling the rapier bar using compressed air. In order to position the rapier bar accurately, however, guidance across a larger zone than the zone in which this rapier bar is in this case cooled with compressed air is desired.
Preferably, the air circuit is coupled to the compressed air device of the rapier weaving machine in which the guide device is accommodated.
Preferably, the air circuit in the guide is limited to one guide element, so that the number of couplings with compressed air lines (from other parts of the air circuit or the compressed air device) is limited.
In one or more air-guiding zones and/or in the zones next to these air-guiding zones, cooling by means of compressed air may, where necessary, be supplemented by cooling by means of coolant.
Water or a water-based liquid are preferably chosen as coolant.
The cooling circuit preferably forms part of a water cooling circuit of the rapier weaving machine in which the guide device is accommodated.
The cooling circuit preferably extends along virtually the entire length of the guide, viewed in the longitudinal direction of the guide.
The cooling circuit may be arranged at least partly in the guide, but may also be arranged at least partly outside this guide in the guide device, for example in the support structure of the guide device, such as for example in a beam adjacent to the rapier bar.
Said air circuit and/or said cooling circuit may be formed in several ways in the one or more guide elements. It is, for example, possible to provide these by drilling channels into these guide elements or by 3D-printing these guide elements, with the air circuit and/or the cooling circuit being provided herein as recesses.
Drilling greatly increases the selection of materials from which a guide element may be produced.
3D-printing makes it possible to intertwine channels from which the air circuit is formed with channels from which the cooling circuit is formed, in which case an overlapping zone in which both cooling with compressed air and cooling with coolant are provided may be used to the greatest possible extent.
Instead of forming the air circuit and/or the cooling circuit by drilling or 3D-printing, a guide element from a guide device according to the present disclosure may, for example, also be produced via extrusion or pultrusion, with the necessary channels being provided in this guide element in order to form (if desired together with other guide elements or other parts of the guide device) the cooling circuit and the air circuit.
There are several materials which are suitable for forming the one or more guide elements thereby. The material (or the materials) of a guide element is (are) selected, on the one hand, in order to be able to ensure good guidance and, on the other hand, to be able to ensure good cooling. In order to ensure good cooling, a good heat-conducting material is preferably selected. To this end, these one or more guide elements may be made, for example, from steel, aluminium, bronze, magnesium, etc.
In a more particular embodiment of a guide device according to the present disclosure, the guide comprises exactly one guide element.
If, in this case, the air circuit is provided in a said air-guiding zone, then this air-guiding zone preferably extends along a length which is virtually half the length along which the guide element extends. In this way, it is possible to achieve a good balance between, on the one hand, good guidance and, on the other hand, good cooling with limited costs for compressed air. This length is viewed in a longitudinal direction along the direction of the movement trajectory of the rapier bar. The guide element preferably substantially extends in this longitudinal direction.
In embodiments with exactly one guide element, this guide element is preferably fixedly arranged in the guide device. A fixedly arranged guide element may be coupled to a compressed air device more easily.
In another more particular embodiment, the guide comprises several guide elements.
With a guide comprising several guide elements, at least one of these guide elements is preferably configured as an air-guide element, in which a said air-guiding zone is arranged.
By providing several guide elements and configuring at least one of them as an air-guide element, it is easier to adapt such a guide to be accommodated in different types of rapier weaving machines and in this case also guide different types of rapier bars. Depending on the rapier weaving machine and/or rapier bar, the movement trajectory of the rapier bar may have to be guided, for example, for a relatively short or a relatively long section in order to be able to ensure a more accurate positioning of the rapier. In this case, a respective air-guide element may be supplemented with one or more additional guide elements in order to form the guide together. These one or more additional guide elements may be produced in a less expensive way than this air-guide element. If desired, the air-guide element may, for example, be made from a different material than the one or more additional guide elements.
Preferably, the guide comprises one or more subcircuits of the cooling circuit, so that the necessary cooling may be provided as close as possible to the rapier bar and in locations where this is most desirable due to the friction during guiding of the rapier bar.
In embodiments comprising several guide elements, preferably several of these guide elements each comprise a subcircuit of the cooling circuit in order to ensure the necessary cooling.
Still more preferably, these subcircuits are then mutually coupled by one or more couplings which are arranged substantially outside the guide. Using such external couplings makes it easier to ensure the tightness of the couplings. When guide elements are directly connected to each other and the subcircuits in this case are also directly connected to each other, it is more difficult to ensure the tightness.
Preferably, such external couplings which are arranged substantially outside the guide are in this case produced by means of flexible lines.
In one embodiment comprising several guide elements, several guide elements are preferably at least partly arranged behind each other, viewed in the longitudinal direction of the guide (the direction of the movement trajectory of the rapier bar). Several guide elements together may form one continuous guide. Alternatively, one or more such guide elements may be arranged at an intermediate distance apart. By arranging guide elements at an intermediate distance apart, distributed along the longitudinal direction, the zone in which the rapier bar may be heated by friction may be limited, while still guiding the rapier bar over a relatively long distance.
In a more particular embodiment, at least one of the guide elements is arranged in the guide device so as to be displaceable along the longitudinal direction.
By providing a guide element so as to be displaceable, the contact zone between the guide and the rapier bar may be limited while still guiding this rapier bar for as long a distance as possible.
If one of the guide elements of such an embodiment is configured as an air-guide element, then this air-guide element is preferably fixedly arranged in the guide device.
The object of the present disclosure is in addition also achieved by providing an assembly of a rapier bar, drive means for driving this rapier bar and a guide device comprising a guide with one or more guide elements for guiding this rapier bar, wherein this guide device is provided with an air circuit through which compressed air can flow and which is provided with perforations for cooling the rapier bar by means of compressed air, and wherein this assembly is provided with a cooling circuit through which coolant can flow for cooling the rapier bar by means of coolant.
In this case, the cooling circuit is preferably as close as possible to the rapier bar to be cooled.
The cooling circuit of such an assembly according to the present disclosure preferably forms part of the guide device.
This guide device is preferably configured as an above-described guide device according to the present disclosure.
The drive means of an assembly according to the present disclosure may be produced in various ways. These may for example comprises a gear wheel, in which the rapier bar comprises a gear rack in which this gear wheel engages.
Preferably, the guide of the guide device is arranged at least partly at the location of the drive means. If these drive means comprise a said gear wheel, the guide is preferably arranged at the location of this gear wheel, preferably on a side of the rapier bar opposite the side in which the gear wheel engages in the gear rack of the rapier bar.
If the guide device of an assembly according to the present disclosure comprises a said air-guiding zone, this air-guiding zone preferably extends at least at the location of the drive means.
In this case, the air-guiding zone preferably extends on one side of the drive means along the length of the guide, viewed in the longitudinal direction.
In a particular embodiment of an assembly according to the present disclosure, the guide comprises several guide elements, of which at least one guide element is a guide element in which the cooling circuit partly extends and which is arranged on a side of the rapier bar which is opposite the side of the rapier bar on which the other guide elements are arranged.
The object of the present disclosure is furthermore also achieved by providing a rapier weaving machine for weaving a fabric which comprises an above-described assembly according to the present disclosure.
In this case, the rapier weaving machine preferably comprises a central compressed air device by means of which the air circuit of the assembly is coupled.
Furthermore, the rapier weaving machine preferably comprises a central cooling circuit of which the cooling circuit of the assembly forms part.
If the assembly of a rapier weaving machine according to the present disclosure comprises a guide device with an abovementioned air-guiding zone, this air-guiding zone extends on the side of the fabric to be woven, preferably at least at the end of the guide.
At the point where the rapier bar leaves the guide, this rapier bar specifically typically experiences a great deal of friction. By allowing the air-guiding zone to extend up to this point, it is possible to limit this friction.
If the air-guiding zone extends on one side of the drive means along the remaining length of the guide, as described above, then this side is preferably turned towards the fabric to be woven.
In order to limit warming up at the location of the point where the rapier bar leaves the guide even more, the assembly of a rapier weaving machine according to the present disclosure preferably is an above-described assembly of which the at least one guide element in which the cooling circuit partly extends and which is arranged on the side of the rapier bar opposite the side of the rapier bar on which the other guide elements are arranged, is arranged near the end of the guide on the side of the fabric to be woven.
The present disclosure will now be explained in more detail by means of the following description of a preferred embodiment of a guide device for a rapier bar according to the present disclosure. The sole aim of this description is to provide illustrative examples and to indicate further advantages and features of the disclosure, and can thus not be interpreted as a limitation of the area of application of the disclosure or of patent rights defined in the claims.
In this description, reference numerals are used to refer to the attached drawings, in which:
In this detailed description, the terms front, rear, top, bottom and side refer to the respective side of the guide (1), viewed in a rapier weaving machine, with respect to a fabric which is woven therewith, which extends substantially horizontally during weaving. In this case, a front view is a view of this guide (1) seen from the fabric. The illustrated guides (1) may be rotated through 90° or 180° in other types of rapier weaving machines and/or for guiding a second rapier bar (3) in a double-face weaving machine.
In the figures, various embodiments of guides (1) of guide devices according to the present disclosure are illustrated. By means of each of these guides (1), the movement of a corresponding rapier bar (3) in a rapier weaving machine may be guided.
In addition to the illustrated guide (1), corresponding guide devices also comprise a support structure (not shown) by means of which this guide (1) is attachable to a rapier weaving machine. In order to be able to attach the guides (1) to the support structure, each of these guides (1) is provided with mounting slots (15).
Furthermore, these guide devices may also comprise one or more additional corresponding guides (1) for guiding one or more additional rapier bars (3).
By means of the illustrated guides (1), the movement trajectory of a rapier bar (3) in a rapier weaving machine is guided. In this case, the rapier bar (3) is driven in the rapier weaving machine by means of drive means (4) to introduce a rapier with a weft yarn in a shed between warp yarns in order to form a fabric. In the embodiment illustrated in
In the illustrated embodiments, the movement trajectory of the rapier bar (3) is guided by the guide (1) on only one side. In this case, this is the side opposite the side on which the gear wheel (4) engages with the rapier bar (3). In alternative embodiments, it is also possible to guide the movement trajectory of the rapier bar (3) on several sides.
If a said rapier band is provided instead of the illustrated rapier bar, the movement trajectory only has to be provided for the part of the illustrated guide (1) between the gear wheel (4) and the fabric. Additional cooling may then also be provided in the complete arc where the gear wheel (4) and the rapier band engage with each other.
In the first embodiment which is illustrated in
Instead of accommodating the air-guide element (10) in a cavity (20) in such a second guide element (2), it would also be possible to attach one or more separate guide elements (2) in front of and/or behind the air-guide element (10) in order to form an alternative guide (1). In this case, such separate guide elements (2) may be securely fitted with respect to the air-guide element (10) or be arranged so as to be displaceable with respect to this air-guide element (10). In this case, these may be arranged so as to adjoin the air-guide element (10) or may be arranged at an intermediate distance from this air-guide element (10). One or more of such separate guide elements (2) may also be configured as an air-guide element (10).
In addition to said two guide elements (2), the guide (1) in the first embodiment also comprises a third guide element (2) which, in the mounted position, as illustrated in
By designing the guide (1) in the form of various guide elements (2), it is possible to produce one guide element (2) (in the illustrated first embodiment the air-guide element) for different types of guides (1) in an identical manner, while it is also possible to produce different types of guides (1) by supplementing this guide element (2) with other guide elements, for example having different cooling options and/or different dimensions and/or different guiding options, etc.
In the second embodiment, which is illustrated in
In the illustrated embodiments, the guides (1) are provided to be fixedly arranged in a rapier weaving machine. In alternative embodiments, it is also possible to arrange one or more guide elements (2) of such a guide (1) so as to be displaceable in a direction along the movement trajectory of the rapier bar (3), so that the movement trajectory of this rapier bar (3) may be guided over a longer distance.
Each illustrated air-guide element (10) is provided with an air circuit (5) which is produced by the following:
Alternatively and/or additionally, such channels (21, 22, 23, 7) could also be 3D-printed and/or be produced via extrusion and/or pultrusion.
Instead of producing perforations (7) when drilling channels, it would also be possible to provide one or more relatively large apertures in the underside of the guide element (2) which connect to one or more compressed-air channels in this guide element (2). A membrane may be attached in such apertures which is provided with the necessary perforations.
In the illustrated embodiments, a connection (12) is provided on the access channel (23) in order to couple the air-guide element (10) with the central compressed-air device of the rapier weaving machine. When forcing compressed air through the resulting air circuit by means of the central compressed-air device, air is thus forced through the perforations (7) in order to cool the rapier bar (3) by means of this compressed air.
The access channel (23) is preferably provided as close as possible to the rear side of the corresponding guide element (10), so that the connection (12) with the central compressed-air device may be provided as close as possible to this central compressed-air device. In
In the various embodiments, the perforations (7) are arranged in an air-guiding zone (Z) which has a shorter length (1) than the length (L) along which the guide (1) extends.
In the first embodiment, several rows and columns of these perforations (7) are arranged centrally in an air-guiding zone (Z) in the bottom surface of the air-guide element (10). In this embodiment, this air-guiding zone (Z) is situated at the location of the gear wheel (4).
In the second and in the third embodiment, the length 1 of the air-guiding zone (Z) is virtually half the length (L) of the guide. In these embodiments, in each case, on the one hand, at the location of the gear wheel (4) a larger concentration of these perforations is present and, on the other hand, at the location of the end (14) of the guide (1) on its front side, as may be seen in
Furthermore, several water channels (17) are drilled into each illustrated guide element (2) via the ends and side walls of these guide elements (2) and these water channels (17) are closed. Furthermore, access channels (24) to these water channels (17) are drilled in order together to form a water circuit (8) in this guide element (2). In this case, subcircuits (8a, 8b, 8c) are formed in each case in the first embodiment which are mutually couplable to external couplings (11), as may be seen in
In the illustrated embodiments, the water circuit (8) in each case extends over virtually the entire length (L) of the guide (1).
Instead of drilling the water channels (17) and the access channels (24), these may alternatively and/or additionally also be 3D-printed and/or be produced via extrusion and/or pultrusion.
Each of the water circuits (8) is provided with two connections (13) in order to be able to couple this water circuit (8) with water lines (9) (see
When water from the central water circuit flows through the water circuit (8), the rapier bar (3) may be water-cooled.
The air-guide element (10) from the first embodiment is furthermore provided with cooling ribs (25) in order to increase the cooling surface of this air-guide element (10).
Number | Date | Country | Kind |
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2019/5298 | May 2019 | BE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2020/054129 | 5/1/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/225682 | 11/12/2020 | WO | A |
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Number | Date | Country |
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Entry |
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Search Report for International Patent Application PCT/IB2020/225682, dated Nov. 23, 2020. |
Number | Date | Country | |
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20220220645 A1 | Jul 2022 | US |