This application is a national phase of PCT/EP2016/068305, filed Aug. 1, 2016, and claims priority to BE 2015/0227, filed Aug. 26, 2015 and BE 2015/0210, filed Aug. 26, 2015, the entire contents of which are hereby incorporated by reference.
The invention relates to a drive mechanism for driving a heald frame of a weaving machine comprising a sensor device detecting the presence of a swivel lever of the drive mechanism in a measuring position. The invention further relates to a method for detecting the presence of a swivel lever of the drive mechanism in a measuring position.
More in particular, the invention relates to a drive mechanism, wherein the drive mechanism comprises a crank rotating about a crank axis, a coupling rod and the swivel lever having a first arm and a second arm, wherein the swivel lever is swivelable to-and-fro about a swivel axis between an upper position and a lower position, wherein the coupling rod is linked to the crank by a first hinged joint, which first hinged joint is eccentric to the crank axis, and the coupling rod is linked to the first arm of the swivel lever by a second hinged joint. The crank, the coupling rod and the swivel lever form a four-link system, also referred to as quadric link.
EP 1 486 597 A2 and EP 1 715 090 A2 disclose shed-forming devices having a plurality of quadric links for converting rotational movements of a plurality of drive shafts into a reciprocal movement of heald frames.
In order to adjust the stroke of the heald frame, a location of the second hinged joint between the coupling rod and the first arm of the swivel lever is adjusted. The movement of the heald frame needs to be synchronized with the main shaft of the weaving machine. For this purpose, EP 1 715 090 A2 discloses a control apparatus, wherein a sensor device comprising a proximity sensor arranged stationary at the weaving machine and a detected portion attached to the swivel lever is provided for detecting the presence of a swivel lever in the area of one of the upper or the lower position. The duration of the signal generated is evaluated in order to determine the turning point of the movement of the swivel lever at the midpoint of the signal.
It is an object of the present invention to provide a drive mechanism with a swivel lever and with a sensor device allowing for a reliable detection of the presence of the swivel lever of the drive mechanism in a measuring position between an upper position and a lower position. It is a further object of the present invention to provide a method for detecting the presence of the swivel lever of the drive mechanism in a measuring position between an upper position and a lower position.
These objects are solved by a drive mechanism with the features of claim 1, by a method with the features of claim 10, and by the dependent claims.
According to a first aspect of the invention, a drive mechanism for driving a heald frame of a weaving machine is provided, the drive mechanism comprising a sensor device, a crank rotating about a crank axis, a coupling rod, and a swivel lever having a first arm and a second arm, wherein the swivel lever is swivelable to-and-fro about a swivel axis between an upper position and a lower position, and wherein the coupling rod is linked to the crank by a first hinged joint, which first hinged joint is eccentric to the crank axis, and wherein the coupling rod is linked to the first arm of the swivel lever by a second hinged joint, wherein the sensor device is arranged for detecting a state at which the swivel lever reaches a measuring position, which measuring position is located between the upper position and the lower position, wherein the sensor device comprises at least three members comprising both a target set with one or more targets and a detector set with one or more detectors, wherein one of the detector set and the target set is arranged at the swivel lever and the other one is arranged stationary on the weaving machine, wherein targets of the target set and/or detectors of the detector set have different characteristics for generating a first signal when approaching the measuring position from the upper position or when departing from the measuring position towards the upper position and for generating a second signal when approaching the measuring position from the lower position or when departing from the measuring position towards the lower position, wherein the second signal differs from the first signal.
As the measuring position is not one of the extreme positions, this means one of the upper position and the lower position, the swivel lever is moved twice per complete movement cycle of the heald frame past the measuring position, wherein the swivel lever is moved either clockwise or counterclockwise. According to the invention, the sensor device is arranged for generating a first signal pattern, comprising for example the first signal followed by the second signal, when the swivel lever is moved clockwise past the measuring position, and for generating a second signal pattern, comprising for example the second signal followed by the first signal, when the swivel lever is moved counterclockwise past the measuring position. Hence, by evaluating the signal pattern, the direction of rotation of the swivel lever can be determined.
The sensor device can be designed suitable by a person skilled in the art considering prevailing circumstances in a weaving mill as well as space limitations on the weaving machine. In one embodiment, a sensor device comprising a Hall effect sensor and two magnets of different polarity is provided. In alternative, a sensor device comprising color-sensitive detectors and two targets with different color is provided. For a simple wiring of the detector set, the detector set in preferred embodiments is arranged stationary, wherein a target set using targets that are operated without energy are provided at the swivel lever. However, it is also possible to arrange the detector set at the swivel lever and to transmit the signals from the detector set wirelessly to a processing device.
In a preferred embodiment, the first signal and the second signal are both binary signals, wherein the first signal and the second signal differ in properties, in particular differ in signal length. A binary signal has two levels, namely a low level and a high level. Preferably, a level of the signal detected at the detector set is low in case no target of the target set is in the range of the detector set, and high in case a target of the target set is in the range of the detector set. This allows for a cost-efficient solution and a simple evaluation of the signals. In preferred embodiments, the target set and the detector set are chosen, so that the first signal and the second signal both comprise a rising edge and a subsequent falling edge generated when approaching the measuring position and when departing from the measuring position.
In one embodiment, the sensor device comprises two detectors and one target, wherein a first signal is generated when the target is in the range of the first detector and a second signal is generated when the target is in the range of the second detector, wherein the first detector and the second detector have different ranges.
In a preferred embodiment, for a cost-efficient solution the three members of the sensor device comprise a first target, a second target and a first detector.
In preferred embodiments, in a state at which the swivel lever of the drive mechanism is arranged in the measuring position, the detector is arranged at least approximately halfway between the first target and the second target, wherein neither the first target nor the second target is in the range of the detector. This allows for a simple evaluation of the signal course in order to determine the state, when the swivel lever is arranged in the measuring position. For this purpose, in an example encoder pulses of a drive motor driving the crank of the drive mechanism are counted between a falling edge of a previous signal generated when moving past the measuring position and a rising edge of the successive signal generated when moving past the measuring position, and the measuring position is identified as the position related to the midpoint of the encoder pulses.
In one embodiment, the first target and the second target are magnets or optical elements of different size. In a preferred embodiment, the first target and the second target are protrusions that differ in size, in particular in length along the movement path of the targets with respect to the detector. The presence of the protrusions is detectable by a detector.
In preferred embodiments, the measuring position is the central position of the swivel lever, wherein the central position of the swivel lever is between the upper position and the lower position. In the context of the application, the central position of the swivel lever is defined as the position that corresponds at least approximately to the closed shed position of a heald frame linked to the swivel lever, in other words a position that is located halfway or approximately halfway between the upper position and the lower position of the swivel lever. In the area of the central position, the swivel lever is moved with a higher speed than at the extreme positions. In other words, compared to the extreme positions the swivel lever is moved over a larger angular range for a given angular movement of the crank driven by the drive motor. Therefore, using the central position allows a very accurate determination of an encoder counter value of the drive motor driving the crank of the drive mechanism, and, thus, a state at which the swivel lever has reached the measuring position.
The targets may be arranged at a suitable position on the swivel lever, wherein in one embodiment, an additional arm is provided for attaching the targets to the swivel lever. Such an arm is shown in EP 1 715 909 A2. Preferably, the protrusions are provided at an edge of the second arm of the swivel lever. In preferred embodiments, the second arm extends horizontally when the swivel lever is arranged in the measuring position.
In preferred embodiments, a location of the second hinged joint is adjustable with respect to the first arm of the swivel lever for adjusting a stroke of the heald frame moved by the drive mechanism. Preferably, the swivel lever is designed in such way that in all intended locations of the second hinged joint with respect to the first arm of the swivel lever, the second hinged joint is situated on an arc of an imaginary circle when the swivel lever is in the central position between the upper position and the lower position, wherein the imaginary circle has a radius that is equal to the distance between the first hinged joint and the second hinged joint, and the imaginary circle has a center that coincides with the crank axis. With this design, when adjusting the stroke, the central position of the swivel lever remains the same within acceptable tolerances, and thus a central position of the heald frame also remains the same within acceptable tolerances. The adjustment of the stroke may be carried out in any position of the swivel lever, and the adjustment does not necessarily have to be carried out while the swivel lever is in the central position.
In preferred embodiments, the first arm of the swivel lever is curved and the location of the second hinged joint is adjustable, preferably steplessly adjustable, along the first arm, wherein a curvature of the first arm is chosen so that upon adjusting the location of the second hinged joint along the first arm, the second hinged joint remains situated on the arc of the imaginary circle.
In preferred embodiments, a processing device is provided for determining a state, at which the swivel lever reaches the measuring position and/or for determining the stroke of the heald frame using the first signal and the second signal. The processing device in one embodiment is integrated in a central processing device of the weaving machine. In other embodiments, a separate processing device is provided that communicates with the central processing device in order to synchronize the movement of the heald frame to the main shaft of the weaving machine. The main shaft of the weaving machine is, for example, a virtual shaft that rotates in accordance with the weaving cycle, wherein the main shaft is at an angle of zero degrees each time at beat-up of a weft thread and rotates over one revolution between two beat-ups.
According to a second aspect of the invention, a method for detecting the presence of a swivel lever of a drive mechanism for driving a heald frame of a weaving machine in a measuring position is provided, wherein the drive mechanism comprises a sensor device, a crank rotating about a crank axis, a coupling rod, and a swivel lever having a first arm and a second arm, wherein the swivel lever is swivelable to-and-fro about a swivel axis between an upper position and a lower position, and wherein the coupling rod is linked to the crank by a first hinged joint, which first hinged joint is eccentric to the crank axis, wherein the coupling rod is linked to the first arm of the swivel lever by a second hinged joint, and wherein the measuring position is located between the upper position and the lower position, the method comprising generating a first signal by the sensor device when approaching the measuring position from the upper position or when departing from the measuring position towards the upper position and generating a second signal by the sensor device when approaching the measuring position from the lower position or when departing from the measuring position towards the lower position, wherein the second signal differs from the first signal.
As two signals are generated, a state, when the swivel lever reaches the measuring position during a movement from the upper position to the lower position, can be distinguished from a state, when the swivel lever reaches the measuring position during a movement from the lower position to the upper position.
In preferred embodiments, the first signal and the second signal are both binary signals, wherein the first signal and the second signal differ in properties, in particular differ in signal length. In particular, in preferred embodiments, a signal having a high level of a first duration or length is generated as the first signal, and a signal having a high level of a second duration or length is generated as the second signal, wherein the second duration or length differs from the first duration or length. For example, the duration or length can be determined in an angular movement of the drive motor.
In preferred embodiments, no signal is generated when the swivel lever is in the measuring position, wherein when moving past the measuring position, the position halfway between the first signal and the second signal is determined as the measuring position.
Any position between the upper position and the lower position may be used as the measuring position. For a simple evaluation, in preferred embodiments the measuring position is the central position between the upper position and the lower position.
In one embodiment, a location of the second hinged joint with respect to the first arm of the swivel lever is adjustable, wherein preferably the location of the second hinged joint is adjusted in such way that the second hinged joint remains situated on an arc of an imaginary circle when the swivel lever is in the central position between the upper position and the lower position, wherein the imaginary circle has a radius that is equal to the distance between the first hinged joint and the second hinged joint, and the imaginary circle has a center that coincides with the crank axis. Hence, when adjusting the stroke, the central position remains at least within acceptable tolerances unchanged.
In preferred embodiments, a stroke of the heald frame is determined using the first signal and the second signal. The stroke can be calculated for example by using the duration of the first signal, the duration of the second signal and/or a difference in duration of the first signal and the second signal.
In preferred embodiments, signals of the sensor device are transmitted to a drive motor drivingly coupled to the crank of the drive mechanism, and the drive motor is driven towards the measuring position to synchronize the drive mechanism with a main shaft of the weaving machine.
Preferably, each drive mechanism is driven by an associated drive motor, wherein a synchronization is performed for all drive motors, in other words a synchronization is performed for each of the drive motors with the main shaft of the weaving machine.
Further characteristics and advantages of the invention will emerge from the following description of the embodiments schematically illustrated in the drawings. Throughout the drawings, the same elements will be indicated by the same reference numerals. In the drawings:
The drive mechanism 2 for driving the heald frame 1 comprises a crank 3 rotating about a crank axis 4, a coupling rod 5, and a swivel lever 6. The swivel lever 6 is swivelable to-and-fro about a swivel axis 7 between an upper position and a lower position. The swivel lever 6 has a first arm 8, a second arm 9 and a third arm 10. The drive mechanism 2 further comprises a second swivel lever 11, that is swivelable to-and-fro about a second swivel axis 12 between an upper position and a lower position. The second swivel lever 11 is linked to the third arm 10 of the swivel lever 6 by means of a connecting rod 13 and driven by the swivel lever 6 to conjointly move with the swivel lever 6.
The heald frame 1 is linked to the second arm 9 of the swivel lever 6 by means of a lifting rod 14 and a fixation element 15 that is guided in the weaving machine. The second swivel lever 11 is also linked via a lifting rod 14 and a fixation element 15 to the heald frame 1.
The coupling rod 5 of the drive mechanism 2 is linked to the crank 3 by a first hinged joint 16, which first hinged joint 16 is eccentric to the crank axis 4. Further, the coupling rod 5 is linked to the first arm 8 of the swivel lever 6 by a second hinged joint 17.
In the embodiment shown, a mounting element 18 is provided and the coupling rod 5 is mounted to the first arm 8 by means of a mounting element 18. The mounting element 18 is slidably mounted to the first arm 8 and fixable in a mounting position at the first arm 8. The coupling rod 5 is pivotally mounted to the mounting element 18 by the second hinged joint 17. For adjusting a stroke of the heald frame 1, a location of the second hinged joint 17 is adjustable with respect to the first arm 8 of the swivel lever 6 by moving the mounting element 18 along the first arm 8. The closer the mounting element 18 and, hence, the location of the second hinged joint 17 is moved towards the swivel axis 7, the larger the stroke of the heald frame 1. The farther the mounting element 18 and, hence, the location of the second hinged joint 17 is moved away from the swivel axis 7, the smaller the stroke of the heald frame 1.
In the embodiment shown, the first arm 8 of the swivel lever 6 is curved and the location of the second hinged joint 17 is adjustable along the first arm 8 by sliding the mounting element 18 along the first arm 8. A curvature of the first arm 8 is chosen so that upon adjusting the location of the second hinged joint 17 along the first arm 8, the second hinged joint 17 remains situated on an arc of an imaginary circle 19 when the swivel lever 6 is in the central position, which imaginary circle 19 will be explained with reference to
When changing the location of the second hinged joint 17 with respect to the swivel lever 6, the orientation or the relative angle of the crank 3 in a state at which the swivel lever 6 of the drive mechanism 2 is in its central position is also changed. Hence, after adjusting the location of the second hinged joint 17, a processing device 38 for the drive mechanism 2 needs to be calibrated again for a synchronization of the movement of the heald frame 1 with a main shaft of the weaving machine.
In an alternative embodiment, during an adjustment of the location of the second hinged joint 17 for changing the stroke of the heald frame 1, the crank 3 is held in position and the coupling rod 5 is moved with respect to the swivel lever 6 and the crank 3. Hence, the swivel lever 6 is moved out of its central position.
For a synchronization with the main shaft of the weaving machine, after adjusting of the location of the second hinged joint 17, the crank 3 in preferred embodiments is driven to move the swivel lever 6 into a measuring position 26 (indicated in
In preferred embodiments, the measuring position is the central position of the swivel lever 6 between the upper position and the lower position. Using the central position is advantageous as in the area of the central position the swivel lever 6 is moved with a higher speed than at the extreme positions, this means compared to the extreme positions the swivel lever 6 is moved over a larger angular range for a given angular difference of the drive motor 31. This allows determining an encoder counter value of the drive motor 31 very accurately at a state when the measuring position is reached. As discussed above, with an appropriate geometry, the central position remains almost constant when changing the stroke. Hence, a sensor device 20 can be positioned stationary and there is no need to adjust the position of the sensor device 20 after changing the stroke.
In one embodiment, a gear box 40 is arranged between the drive motor 31 and the crank 3. The gear box 40 has a transmission ratio of seven, this means the drive motor 31 makes seven revolutions per revolution of the crank 3, and the precision for determining an orientation of the crank 3 is seven times the precision for determining an angular difference of the drive motor 31 that is determined by the incremental encoder 39.
Each measuring position between the upper position and the lower position of the swivel lever 6 is reached twice per revolution of the crank 3. Therefore, preferably provision is made to distinguish the two states when the measuring position is reached, this means two orientations of the crank 3.
The sensor device 20 comprises at least three members. In the embodiment of
The first target 21 and the second target 22 have different properties for generating a first signal 24 when approaching the measuring position from the upper position or when departing from the measuring position towards the upper position and for generating a second signal 25 when approaching the measuring position from the lower position or when departing from the measuring position towards the lower position, wherein the second signal 25 differs from the first signal 24.
In the embodiment shown, the first target 21 and the second target 22 are protrusions that differ in size, in particular in length along the movement path 42 of the targets 21, 22 with respect to the detector 23, which protrusions are provided on the edge 41 of the second arm 9 of the swivel lever 6 for generating binary signals that are different from each other, in particular the first signal 24 and the second signal 25 are both binary signals, wherein the first signal 24 and the second signal 25 differ in properties. The detector 23 is arranged stationary on the weaving machine. In the embodiment shown, in a state of the drive mechanism 2 at which the swivel lever 6 is arranged in the measuring position shown in
As shown in
Depending on the direction of rotation of the swivel lever 6, the first target 21 or the second target 22 is moved first within the range of the detector 23 when moving the second arm 9 of the swivel lever 6 with the target set past the detector 23. Hence, depending on the direction of rotation of the swivel lever 6 the first signal 24 is generated before the second signal 25 or the first signal 24 is generated after the second signal 25. With the information about the arrangement of the first target 21 and the second target 22 on the swivel lever 6, the sensor device 20 allows for a determination of a direction of rotation of the swivel lever 6 from the signal course 43, as shown in
In addition, the signal course 43 of the sensor device 20 may also be used for determining a stroke of a heald frame with sufficient accuracy. In an embodiment, the stroke of the heald frame 1 is determined using the first signal 24 and the second signal 25.
For determining the stroke, the angular position or orientation of the crank 3 and/or an encoder counter value of the drive motor 31 driving the crank 3 when reaching each of a measuring position 26, an outer edge 35 of the first signal 24, this means the edge of the first signal 24 that is further away from the determined measuring position 26, and an outer edge 37 of the second signal 25, this means the edge of the second signal 25 that is farther away from the determined measuring position 26, are determined, and the angular difference and/or the difference in encoder count values for moving from the measuring position 26 to the outer edge 35 of the first signal 24 and from the measuring position 26 to the outer edge 37 of the second signal 25 is calculated. The difference in actual size, in particular the difference in actual length of the first target 21 and the second target 22 is known. Hence, using the determined angular difference and/or the calculated difference in encoder count values, the above known difference in the actual sizes as well as known geometrical lengths and angles of the drive mechanism 2, the stroke can be determined. As alternative, the stroke can be determined from the angular difference and/or the calculated difference in encoder count values based on a movement between both outer edges 35 and 37 and/or based on a movement between both inner edges 34 and 36.
In order to allow for a high flexibility, each heald frame 1 of a weaving machine is provided with an assigned drive mechanism 2, wherein all cranks 3 of the drive mechanisms are driven by an assigned drive motor 31.
Hereby, the signals of the sensor device 20, in particular the signals of the detectors 23.1 to 23.16 that respectively are assigned to a crank 4.1 to 4.16, are transmitted to a drive motor 31.1 to 31.16 drivingly coupled to the crank 3.1 to 3.16 of the drive mechanism 2.1 to 2.16, and the drive motor 31.1 to 31.16 is driven towards the measuring position to synchronize the drive mechanism 2.1 to 2.16 with the main shaft of the weaving machine. As the swivel lever 6.1 to 6.16 reaches the central position twice per revolution of the crank axis 4.1 to 4.16, there are two states per revolution of the crank axis 4.1 to 4.16 to synchronise the drive mechanism 2.1 to 2.16 with the main shaft of the weaving machine. In
As the geometry, in particular the length of the coupling rods 5.1 to 5.16 and hence, the distance of the first hinged joint 16.1 to 16.16 and the second hinged joint 17.1 to 17.16 differs for different drive mechanisms 2.1 to 2.16, the swivel levers 6.1 to 6.16 are individually designed for each drive mechanism 2.1 to 2.16. However, due to the arrangement in pairs for two drive mechanisms 2.1 to 2.16 of a common pair of drive mechanisms 2.1 to 2.16, elements of identical design can be used for some of the drive mechanisms 2.1 to 2.16. Hereby all swivel levers 6.1 to 6.16 are swivelable about a same swivel axis 7. As in a weaving machine the heald frames that are located farther away from the fell line need to move over a larger stroke in order to form a weaving shed, it is advantageous that the length of the cranks for the heald frames that are located farther away from the fell line increases. For example the cranks 4.1 to 4.4 have a same length, the cranks 4.5 to 4.8 are somewhat longer, the cranks 4.9 to 4.12 are still somewhat longer and the cranks 4.13 to 4.16 are the longest, as can be seen in
In
In the context of the application the first arm 8 and the second arm 9 are defined for indicating a different function. Of course in an alternative embodiment the first arm 8 and the second arm 9 can be carried out in one piece.
The drive mechanism and the method according to the invention are not limited to the embodiments described by way of example and illustrated in the drawings. Alternatives and combinations of the described and illustrated embodiments that fall under the claims are also possible.
Number | Date | Country | Kind |
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2015/0210 | Aug 2015 | BE | national |
2015/0227 | Aug 2015 | BE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2016/068305 | 8/1/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/032557 | 3/2/2017 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3991793 | Demuth | Nov 1976 | A |
5050643 | Takegawa | Sep 1991 | A |
5306993 | de Fries | Apr 1994 | A |
5642757 | Froment | Jul 1997 | A |
5646495 | Toyozawa | Jul 1997 | A |
5755267 | Eberhard | May 1998 | A |
6186184 | Eberhard | Feb 2001 | B1 |
6525496 | Bilcke | Feb 2003 | B1 |
6962171 | Krumm | Nov 2005 | B2 |
7594522 | Binder | Sep 2009 | B2 |
7775210 | Schobel (nee Bauer) et al. | Aug 2010 | B2 |
9240083 | Isom | Jan 2016 | B2 |
20180237962 | Sampers | Aug 2018 | A1 |
20180291537 | Sampers | Oct 2018 | A1 |
Number | Date | Country |
---|---|---|
2711797 | Jul 2005 | CN |
102260947 | Nov 2011 | CN |
104420047 | Mar 2015 | CN |
1477598 | Nov 2004 | EP |
1486597 | Dec 2004 | EP |
1715090 | Oct 2006 | EP |
2977592 | Jan 2013 | FR |
H09 111576 | Apr 1997 | JP |
2000064145 | Feb 2000 | JP |
2004316066 | Nov 2004 | JP |
Entry |
---|
International Search Report dated Oct. 28, 2016 in connection with PCT/EP2016/068305. |
Written Opinion of the International Searching Authority issued in connection with PCT/EP2016/068305. |
Belgian Search Report issued in connection with BE 2015/0227. |
Office Action issued in connection with corresponding Chinese Patent Application No. 201680049523. |
Number | Date | Country | |
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20180237962 A1 | Aug 2018 | US |