The invention relates to a mobile drawing-in unit for drawing in warp threads of a warp into elements of a weaving harness, a drawing-in machine having a stationary and a mobile part, and a corresponding drawing-in method.
Before a fabric or a material is produced on a weaving machine by joining warp threads and weft threads, the warp threads must be drawn into a weaving harness following a specific order. The elements of the weaving harness normally include heald frames, healds, drop wires and the reed. In this case, drawing-in means guiding each individual warp thread, which is normally wound on a warp beam in the required length, in each case into the thread guide of a drop wire, a heald and a gap between two teeth of the reed so that the end of the drawn-in warp thread then projects from the reed. The fabric pattern is predefined in this case by assigning the reed to a specific heald frame or introducing it into such a heald frame.
Since normally several hundred to several thousand warp threads are normally wound over a specific width in parallel on a warp beam, this process must be repeated precisely sufficiently frequently until a warp has been completely drawn into a weaving harness. This has been and still is carried out manually as before but machines are also available in various designs which either execute some of the processes (semi-automatic drawing-in machines) or the entire sequence automatically (automatic drawing-in machines).
Semi-automatic drawing-in machines are certainly relatively expensive but have the major disadvantage compared with automatic drawing-in machines that an operator is 100% occupied on the machine and executes the drawing-in process partly manually. In this way, only a slight increase in productivity can be achieved compared with manual drawing-in and the error rate is relatively high.
Automatic drawing-in machines are known and available on the market in various embodiments. They have an independent control for all the processes required for drawing-in warp threads into a weaving harness. The tasks of the operating staff are restricted to preparing and monitoring the sequence and the functions as well as the supply and removal of the starting material. The productivity can thus be increased many times compared with manual drawing-in and the error rate can be reduced substantially.
Known from the patent specification EP 0 460 129 is a drawing-in machine which has a needle-shaped drawing-in member, driveable in an oscillating manner, having a flexible gripper strip which bears a clamping gripper and which has a channel-like guide for the drawing-in member. This should ensure secure and reliable drawing-in of warp threads of all types.
The Japanese patent application JP 0 605 75 95 discloses a stationary drawing-in machine including a moveable machine frame for drawing-in warp threads.
The known disadvantages of such automatic drawing-in machines are, however, their high price, their relatively high space requirement and the fixed location inside the weaving mill. This must be selected so that an efficient flow of material is possible. A subsequent change in the location of a drawing-in machine is only possible with considerable installation effort and expenditure of time as well as interruption of production. This leads to high installation costs and large capacities which are possibly not used.
An advantage of the present invention consists in that the foregoing disadvantages are overcome and in particular a particularly flexible drawing-in of warps is rendered possible in an additionally simple and cost-effective manner.
An essential point of the invention consists in that the drawing-in unit according to the invention is flexible with regard to the location and additionally has a low space requirement. At the same time, its capacity is expandable, i.e. is suitable for a small requirement but can be expanded up to high capacities. Furthermore, only small basic investment costs are required for its procurement and operation.
Thus, in an advantageous embodiment of the drawing-in unit, it is provided that the elements of the weaving harness comprise at least one pair of heald bars and healds which can be placed on these heald bars, and the heald bars can be received in a receiving device and the healds can be fed in a feeding device and in which the drawing-in module is configured for placing the healds on the heald bars. In this case, the heald bars can already be fed in such a manner that they are held in lateral heald frames and inserted together with said heald frames into the receiving device. The basic elements of a weaving harness can thus be received and drawn in on the drawing-in unit. The set-up times are therefore restricted to this unit and not to the feeding of a warp beam bearing the warp to be drawn-in. The unit can thus be made available particularly rapidly and flexibly for drawing-in further thread layers.
In a further preferred embodiment of the drawing-in unit, it is additionally provided that the elements of the weaving harness comprise at least one drop wire supporting rail and drop wires which can be placed on this drop wire supporting rail, in which the drop wire supporting rail can be received in a receiving device and the drop wires can be fed in a feeding device, and the drawing-in module is configured for placing the drop wires on the drop wire supporting rail. As a result, further elements of a weaving harness can be received on the drawing-in unit and drawn in depending on the respective requirements of the desired weaving process. The drawing-in unit can thus be used more flexibly.
In yet another preferred embodiment of the drawing-in unit, it is additionally provided that the elements of the weaving harness comprise a reed which can be received in a receiving device, which is disposed after the healds when viewed in the direction of movement of the warp threads, and the drawing-in module is configured for drawing in the respective warp thread into relevant gaps of the reed and for gradually moving the reed further by a respective gap. As a result, the drawing-in unit can also be used more flexibly. The reed can thereby be held in the receiving device and moved further, for example, contrary to the direction of travel of the drawing-in unit by a suitable mechanism of the drawing-in module so that it remains positioned virtually spatially fixed with respect to the warp.
For operation of the drawing-in unit, this is preferably equipped with an independent compressed air supply and/or an electric power source. As a result, its flexibility is increased considerably since it is freed from cables and independent of external connections, i.e. it can be operated independently and is therefore spatially flexible.
In addition, a control module can be provided for automatic control of the drawing-in unit, in particular, for example, by its drawing-in module. A particularly easy movement of the drawing-in unit is preferably ensured by equipping this with an electric motor for the driving operation. Both these support a largely automated guidance of the unit in a production operation having, for example, a plurality of spatially separated weaving machines and warp beams.
For guidance of such a drawing-in unit, this is preferably equipped with a communication module for its wire-based and/or radio-based control. In a particularly preferred manner, guide cables for the drawing-in unit are laid in the floor of a production workshop, the unit being moved in a wireless independent manner therealong. Driving tasks can be transmitted to the unit in a wireless manner via radio signal.
In principle, the drawing-in unit need not have any specific chassis. Said unit can be moved on rails, for example, which however require previous laying. For movement of the unit, however, this is preferably equipped with wheels so as to ensure a particularly great flexibility.
The initially specified advantage of the present invention is achieved by a drawing-in machine which comprises a stationary part and a mobile part, wherein the stationary part comprises a clamping unit for a warp thread layer and the mobile part comprises the drawing-in unit.
An essential point of the drawing-in machine consists in that the position of the clamping unit can be selected so that it is optimally adapted to the material flow in the weaving mill. The structure of the machine according to the invention thus results in a particularly great flexibility.
The stationary part of the drawing-in machine thereby preferably comprises a clamping device for the warp thread layer. In addition, a retaining unit for a reed can be provided. The drawing-in unit can be transported along the thread layer and the reed for drawing in the warp threads into elements of the weaving harness, and the drawing-in module is configured for drawing in the respective warp thread into healds and/or drop wires and/or related gaps of the reed.
In a preferred embodiment of the method, each of the warp threads is drawn by respectively one appurtenant heald and/or respectively one appurtenant drop wire and/or respectively one appurtenant gap of a reed. Thus, optionally all the essential elements of a weaving harness can be integrated in the drawing-in process, thus ensuring a considerable flexibility with regard to the requirements of the desired weaving process.
Following the drawing-in of the warp into the elements of the weaving harness, the weaving harness with the drawn-in warp threads is removed from the drawing-in machine and the drawing-in machine is preferably positioned on a further thread layer or clamping unit. The drawing-in unit is therefore particularly rapidly available again for another drawing-in process, in which case it can be used completely flexibly spatially.
The mobile drawing-in unit according to the invention should accordingly also be used for operating spatially distributed clamping units with warp threads clamped in a thread layer.
The invention is explained in detail hereinafter with reference to the appended figures. The figures illustrate the individual process steps together with the units used in this case. As a result of the plurality of parts which are the same or have the same effect, these are characterised by the same reference numerals, thus ensuring a good overview. In the figures:
A drawing-in process using the previously described drawing-in machine can accordingly be prepared and executed as follows.
The warp to be drawn in is firstly brought to the clamping unit 60 and the warp thread layer 21 is clamped on the thread frame 62. Depending on the preferred operating mode, this can take place in the horizontal or vertical position of the thread frame 62. After completion, the thread frame 62 is pivoted into the vertical. When using a reed 50, this can be clamped into the retaining unit 70 provided for this purpose.
The drawing-in unit 10 is then driven to the beginning of the warp thread layer 21. At the latest, the drawing-in unit is now prepared for the drawing-in by inserting a required number of heald bars or heald frames 30, 30′ or drop wire supporting rails 40 into the receiving device 32, 42 provided for this purpose according to a drawing-in repeat pattern. In addition, the feeding device 33 or 43 for heald stacks or drop wire stacks is filled and a programming and/or input of the drawing-in repeat pattern is carried out.
The start of the drawing-in process is then triggered. The drawing-in of the warp threads 20, 20′ takes place in a manner known per se in healds 31, drop wires 41 and the reed 50 until the last warp thread programmed according to the drawing-in repeat pattern. The healds 31 and drop wires 41 with warp threads 20, 20′ drawn therein are distributed to the heald bars 30, 30′ or drop wire supporting rails 40 provided for this purpose according to the drawing-in repeat pattern. The last warp threads 20, 20′ drawn into the gaps 52 of the reed 50 project to the front from the reed 50.
During the drawing-in, the drawing-in unit 10 moves sideways from the beginning to the end of the warp thread layer 21 in accordance with the progress of the drawing-in. Once the end of the warp thread layer 21 is reached and the last warp thread 20, 20′ is drawn in, the drawing-in unit 10 stands directly in front of the warp beam 61.
For take down, the reed 50 is released from the retaining unit 70, the heald bars 30, 30′ with the healds 31 and the drop wire supporting rails 40 with the drop wires 41 are raised and removed together with the warp from the clamping unit 60. At the same time, the drawing-in unit 10 can be moved away. Clamping unit 60 and drawing-in unit 10 are thus free again for a next drawing-in process or its preparation.
Consequently, one or more clamping units 60 can be operated with a single drawing-in unit 10. This has the advantage that the capacity of the drawing-in unit 10 can be fully utilised when necessary since drawing-in can be effected almost without interruption on one of the clamping units 60 and only a brief interruption must be made for preparing and taking down and replacing the drawing-in unit 10.
During drawing-in, the frequently heavy warp beams 61 remain stationary. Motor drives for their forward movement are thereby omitted.
Depending on the material flow or topological design of the weaving mill, a single drawing-in unit 10 can serve several clamping units 60 located at a distance from one another such as, for example, in different weaving rooms. Thus, investment costs can be kept low and long transport distances, for example, for heavy warps, can be avoided.
Thanks to the mobility of the drawing-in unit 10, the maintenance of the machine can be carried out at any location and under optimal conditions. Maintenance work is thereby accomplished very efficiently and in a short time.
In addition, the drawing-in unit 10 can be designed to be self-propelled. In correspondingly configured surroundings and with the relevant installation, the drawing-in unit 10 can also be designed to be self-steering and can find its next deployment location independently and without being accompanied by an operator.
Such a person is only required for the preparation and take-down. During drawing-in, the installation runs independently. One person can therefore operate several drawing-in units 10 or clamping units 60.
Number | Date | Country | Kind |
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08405309 | Dec 2008 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CH2009/000381 | 11/30/2009 | WO | 00 | 8/3/2011 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2010/069086 | 6/24/2010 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
1716549 | Hammer | Jun 1929 | A |
3136025 | Noone et al. | Jun 1964 | A |
5136762 | Gironi | Aug 1992 | A |
5184380 | Benz et al. | Feb 1993 | A |
5274894 | Wilhelm et al. | Jan 1994 | A |
5287605 | Badertscher et al. | Feb 1994 | A |
5459913 | Lechner et al. | Oct 1995 | A |
5475906 | Magdika | Dec 1995 | A |
5514234 | Plaschy et al. | May 1996 | A |
5775380 | Roelstraete et al. | Jul 1998 | A |
Number | Date | Country |
---|---|---|
506643 | Apr 1971 | CH |
1384801 | Jan 2004 | EP |
06-057595 | Mar 1994 | JP |
0015888 | Mar 2000 | WO |
0061847 | Oct 2000 | WO |
0068479 | Nov 2000 | WO |
Entry |
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International Search Report for PCT/CH2009/000381 dated Feb. 15, 2010. |
Number | Date | Country | |
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20110283498 A1 | Nov 2011 | US |