BE1026547A1 - Sensor device and method for detecting an abnormal state of a waste ribbon - Google Patents

Abstract

The invention relates to a sensor device and a method for detecting an abnormal state of a waste ribbon in a weaving machine comprising a block (2) with a guide element (3) for the waste ribbon, wherein in a normal state of the waste ribbon the block (2) is mounted in a nominal position, the block (2) being mounted slidably along a trajectory of the scrap ribbon so that the block (2) can be shifted from the nominal position in a direction opposite to the normal direction of motion of the scrap ribbon by forces which act on the block (2) in the aforementioned direction opposite to the normal direction of movement of the waste ribbon.

Description

Sensor device and method for detecting an abnormal state of a waste ribbon.

Technical field and state of the art.

The invention relates to a sensor device and a method for detecting an abnormal state of a waste ribbon at a weaving machine.

JP 56-103076-U shows a weaving machine with a sensor device for detecting a drop in tension of a scrap ribbon containing a lever pivotally mounted about a pivot axis, the lever being held in a first position at a distance from a contact due to a gravity drop ribbon acting on the lever, and due to gravity, the lever is pivoted to a second position, where the lever contacts the contact, in case a tension in the drop ribbon drops below a set value.

Summary of the invention.

It is the object of the invention to provide a sensor device and a method for detecting an abnormal state of a waste ribbon at a weaving machine.

This object is solved by the apparatus and method having the features of claims 1 and 9. Preferred embodiments are defined in the dependent claims.

BE2019 / 0061 [0005] In a first aspect, a sensor device is provided for detecting an abnormal state of a waste ribbon at a weaving machine comprising a block with a guide element for the waste ribbon, wherein in a normal state of the waste ribbon the block in a nominal position, and wherein the block is slidably mounted along a path of movement of the scrap ribbon so that the block can be shifted from its nominal position in a direction opposite to the normal direction of movement of the scrap ribbon by forces acting on the block in the opposite direction to the normal direction of movement of the waste ribbon.

The waste ribbon makes contact with the block at the height of the guide element. Thus, in use, in a normal state, the waste ribbon exerts a force on the block in its direction of movement. In an abnormal condition, forces acting on the block in an opposite direction could be applied by a scrap ribbon being pulled backwards, this means pulled in a direction opposite to its normal direction of movement, for example, when the scrap ribbon is clamped between a cloth winding device.

The waste ribbon guiding element in one embodiment is a guiding groove. In other embodiments, the guide element is a guide eye.

In one embodiment, a proximity sensor is provided, wherein a presence or absence of the block in the nominal position is detectable by the proximity sensor. In one embodiment, the block has a detection plane, the block being considered to be mounted in the nominal position as long as it

BE2019 / 0061 detection area is located within a certain area opposite the proximity sensor, this means as long as the detection area is detectable by the proximity sensor.

In preferred embodiments, at least in the region of the sensor device, the scrap ribbon is moved along an at least substantially linear path of movement, the block being slidably mounted along a linear path. In one embodiment, a guide shaft is provided, the block being mounted slidably along the guide shaft on the guide shaft. In the context of the application, a movement along the guide shaft describes a movement in the axial direction of the guide shaft. The block is provided with a groove or through hole that receives the guide shaft. The guide axis is arranged at least mainly parallel to the path of movement of the waste ribbon.

In one embodiment, the guide shaft is mounted between the wings of a mounting bracket, in particular between two wings of a mounting bracket, each wing being provided with a guide element for the scrap ribbon. The two guide elements define a path of movement of the waste ribbon. In preferred embodiments, the guide elements are aligned relative to one another along an axis that extends parallel to the guide axis. The guide elements for the waste ribbon are in one embodiment each formed by a guide groove, in other embodiments, the guide elements are guide eyes.

In one embodiment, the block is movable along the full length of the guide shaft between the wings of the

BE2019 / 0061 mounting bracket. In preferred embodiments, a movement of the block in the normal direction of movement of the scrap ribbon toward a first wing of the mounting bracket is limited by a stop member. In normal conditions, the scrap ribbon in use exerts a force on the block in its direction of movement by forcing the block against the stop member. The stop element ensures precise and repeatable positioning of the block in the nominal position.

In one embodiment, the block has only one degree of freedom, this means that a movement of the block is limited to the movement along the trajectory of the waste ribbon. In preferred embodiments, the block is further rotatably mounted on the guide shaft, a force being applied to the block to rotate the block about the guide shaft from its nominal position, and the block being held in the nominal position against the aforementioned force by a waste ribbon with a predefined voltage. In other words, the block is slidable from the nominal position as well as rotatable from the nominal position, any one of the movements from the nominal position being detectable, for example, by means of the proximity sensor. In one embodiment, the guide shaft is arranged horizontally, with the forces of gravity acting on the block to rotate the block about the guide shaft from its nominal position. Alternatively or additionally, in embodiments of the invention, biasing force elements, such as spring elements, are provided to force the block out of its nominal position. In this case, in one embodiment, the guide shaft is not arranged horizontally.

BE2019 / 0061 In preferred embodiments, the block is provided with a detection plane, the block being deemed to be mounted in the nominal position as long as the detection plane is within a certain range. The block is at least movable so that the detection plane can be moved out of the defined area. In embodiments, the block is additionally rotatable so that the detection plane can be moved out of the defined area.

In one embodiment, the guide member for the scrap ribbon of the block is a guide eye, wherein an axis of that guide eye and an axis of rotation of the block lie in a center plane of the block, and the detection plane is arranged asymmetrically with respect to the center plane . With this design, a rotation angle by which the detection plane is moved out of the defined area depends on the orientation in which the block is mounted on the guide shaft. Therefore, by removing the block from the guide shaft, rotating the block 180 °, and reassembling the block on the guide shaft, a sensitivity of the sensor device for deviations in a waste ribbon tension can be changed.

In a second aspect, there is provided a method for detecting an abnormal condition of a scrap ribbon at a weaving machine, wherein the scrap ribbon is passed through a block, which block is slidably disposed along a path of movement of the scrap ribbon, in a normal condition of the scrap ribbon, the block is placed in a nominal position, and wherein if the scrap ribbon is moved in a direction opposite to its normal direction of movement, the scrap ribbon exerts a force on the block in said direction opposite to the normal

BE2019 / 0061 The direction of movement of the waste ribbon and the block is moved in the aforementioned direction opposite to the normal direction of movement of the waste ribbon from the nominal position.

In one embodiment, a presence or absence of the block in the nominal position is detected by a proximity sensor.

In one embodiment, the block is movable only along a path of movement of the waste ribbon. In preferred embodiments, the block is additionally rotatably disposed about an axis of rotation extending at least substantially parallel to the path of movement of the scrap ribbon, a force being applied to the block to rotate the block about the axis of rotation from its nominal position, and the block is held in nominal position against the aforementioned force by a waste ribbon with a predefined tension.

Brief description of the drawings.

Hereafter, embodiments of the invention will be described in detail with reference to the drawings. Throughout the drawings, like elements are designated by like reference numbers.

Figure 1 is a perspective view of a front of a first embodiment of a sensor device for detecting an abnormal state of a scrap ribbon at a weaving machine, which is preferably mounted on a right side of a weaving machine;

BE2019 / 0061

Figure 2 shows the sensor device of Figure 1 in a perspective view from the rear in a normal state of a waste ribbon;

Figure 3 shows the sensor device of Figure 2 in a perspective view from the rear in an abnormal state of a waste ribbon;

Figure 4 is a front view of the sensor device of Figure 1 in the normal state of a waste ribbon of Figure 2;

Figure 5 is a front view of the sensor device of Figure 1 in the abnormal state of a waste ribbon of Figure 3;

Figure 6 is a side view of the sensor device of Figure 1 with a first sensitivity arrangement in the normal state of the scrap ribbon as shown in Figure 3;

Figure 7 is a side view of the sensor device of Figure 6 in another abnormal state of a waste ribbon;

Figure 8 is a side view of the sensor device of Figure 6 with a second sensitivity arrangement in the normal state of the scrap ribbon as shown in Figure 3; and

Figure 9 is a perspective view of a front of a second embodiment of a sensor device for detecting an abnormal state of a scrap ribbon at a weaving machine, which is preferably mounted on a left side of a weaving machine.

BE2019 / 0061

Detailed description of embodiments of the invention.

Figures 1 to 8 show a first embodiment of a sensor device 1 for detecting an abnormal state of a scrap ribbon (not shown) at a weaving machine.

The sensor device 1 comprises a block 2 with a guide element 3 for the waste ribbon. The block 2 is mounted on a guide shaft 4. In the embodiment shown, the block 2 is slidably and rotatably mounted on the guide shaft 4 so that the block 2 can slide along the guide shaft 4 and rotate about the guide shaft 4.

The sensor device 1 comprises a mounting support 5 with two parallel wings 6 and a collar beam 11 which is arranged perpendicular to the two wings 6.

The guide shaft 4 is mounted between the wings 6 of the mounting bracket 5, in the shown embodiment the guide shaft 4 is mounted on the mounting bracket 5 by means of bolts 14, 15. Each wing 6 is provided with a guide element 7 for the waste ribbon.

In the embodiment shown, the guide shaft 4 is provided with a stop element 8, whereby a movement of the block 2 towards a first wing 6 of the mounting support 5, which is shown on the right in figure 1, is limited by the stop element 8. The other wing 6 is hereinafter referred to as the second wing 6.

BE2019 / 0061 [0024] The sensor device 1 further comprises a proximity sensor 9 with a cable 12, which is mounted on the collar beam 11 of the mounting bracket 5. The proximity sensor 9 cooperates with a detection surface 10 of the block 2 as explained in more detail below.

In the shown embodiment, the guiding element 3 of the block 2 and the guiding elements 7 in the wings 6 are guiding eyes, wherein a waste ribbon (not shown) is wired through the guiding element 7 at the height of the second wing 6 (left in figure 1), through the guide element 3 of the block 2 and through the guide element 7 provided at the level of the first wing 6. As a result, during normal operation, the waste ribbon is moved from left to right in figure 1, the moving waste ribbon having a force on the block 2 which forces the block 2 towards the stop element 8.

The terms left and right used in the context of the application are only used to describe a position of elements relative to each other and do not limit the arrangement of the sensor device 1 on a weaving machine.

An axis 17 of the guiding element 3 of the block 2 and a rotation axis 18 of the block 2 lie in a central plane 13, indicated by a dotted line. The block 2 shown in Figures 1 to 8 is provided with three designations 16, two designations 16 on a common first part of the block 2 relative to the central plane, and one designation 16 on an opposite second part of the block 2 is provided.

BE2019 / 0061 The guide shaft 4 is arranged horizontally, whereby gravity acting on the block 2 causes rotation of the block 2 about the guide shaft 4 until equilibrium is reached. In case a waste ribbon with a sufficient tension is wired through the guide elements 3 and 7, a rotation of the block 2 is avoided. In case a tension of the waste ribbon falls, the block 2 will rotate about the guide shaft 4 due to the gravitational forces acting on the block 2. In the embodiment shown, a center of gravity of the block 2 and the detection plane 10 are arranged on opposite sides of the guide shaft 4, this means when the center of gravity is moved downwards, the detection plane 10 is moved upwards. In other embodiments, the center of gravity of the block 2 and the detection plane 10 are arranged on the same side of the block 2 relative to the guide axis 4.

Figures 1, 2, 4, 6 and 8 show a normal state of a waste ribbon, in which the detection surface 10 is arranged opposite the proximity sensor 9. In the context of the application, the block 2 is considered to be arranged in a nominal position as long as the detection plane 10 is arranged within a certain area, and thus is detectable by the proximity sensor 9.

The sensor device 1 shown in the figures is suitable for detecting two different abnormal states.

Figures 3 and 5 show a first abnormal state, in which the block 2 is moved out of the nominal position along the guide axis 4. Such a movement of the block 2 is caused by forces acting on the block 2 in a direction opposite to the normal direction of movement of the waste ribbon, this

BE2019 / 0061 means from right to left in figure 1. Such forces are applied to block 2, for example when the waste ribbon is moved in a direction opposite to its normal direction of movement, this means from right to left in figures 1 and 4. When the block 2 moves along the guide axis 4, thus to the left in Figures 1 and 4, the detection surface 10 of the block 2 will move away from the proximity sensor 9 and the proximity sensor 9 will not give a signal. This can be an indication that something is wrong with the waste ribbon, and the weaving machine can be stopped. It will be clear to the skilled person that a path of movement of the block 2 before the detection plane 10 leaves the sensor range of the proximity sensor 9 depends inter alia on a dimension of the block 2 in the axial direction of the guide shaft 4 and a length of the stop element 8 .

Figure 7 shows a second abnormal state, in which the block 2 is rotated about the guide shaft 4 from the nominal position shown in figure 6. Such rotation of the block 2 is caused, for example, by gravitational forces acting on the block 2, in case a waste ribbon tension is not enough to balance gravity.

As shown in Figures 6 and 8, the detection surface 10 is arranged asymmetrically with respect to the central surface 13. The block 2 can be mounted on the guide shaft 4 in two orientations as shown in figures 6 and 8, the orientations are rotated 180 ° relative to each other. A sensitivity to deviations in the waste ribbon tension depends on the orientation of the block 2.

Figure 6 shows a first orientation, also referred to as a sensitive arrangement, with the first part of the block 2 provided

BE2019 / 0061 of two indications 16 above the second part of the block 2 provided with only one indication 16 is arranged. In that orientation, the detection plane 10 extends only a short distance down from a neutral position, in which the center plane 13 is aligned with a central axis of the proximity sensor 9. Thus, a small rotation of the block 2 about the guide axis 4 causes the detection plane 10 to move upward and out of range of the proximity sensor 9. In other words, when the block 2 rotates a small amount, a signal from the proximity sensor 9 already drops.

Figure 8 shows a second orientation, also referred to as a non-sensitive arrangement, wherein the first part of the block 2 provided with two indicia 16 is arranged under the second part of the block 2 provided with only one indication 16, the indicia 16 are not visible in figure 8. With that orientation, compared to the sensitive arrangement, the detection plane 10 extends a greater distance down from a neutral position, in which the center plane 13 is aligned with a central axis of the proximity sensor 9 Thus, compared to the sensitive arrangement, the block 2 can rotate about the guide axis 4 by a greater angle before a signal from the proximity sensor 9 will drop. In other words, when one end of the block 2 is moved downward from the detection plane 10 due to gravity and the detection plane 10 is moved upwards, the proximity sensor 9 continues to measure a signal even if the block 2 is rotated by a greater angle in comparison with the sensitive setup.

The sensor device 1 shown in Figures 1 to 8 is preferably arranged on the right side of a weaving machine,

BE2019 / 0061 in which the waste ribbon moves from left to right in a normal state.

Fig. 9 is a perspective view of a front of a second embodiment of a sensor device 1 for detecting an abnormal state of a scrap ribbon at a weaving machine, which is preferably arranged on a left side of a weaving machine, with the scrap ribbon in a normal state moves from right to left. The sensor device 1 shown in Figure 9 mainly corresponds to the sensor device 1 shown in Figures 1 to 8 and corresponding reference characters are used for the same or similar elements.

In contrast to the embodiment shown in Figures 1 to 8, in the embodiment of Figure 9, the stop element 8 is provided on the second wing 6, shown on the left in Figure 9. In normal operation, the scrap ribbon (not shown) is moved to the right in the drawing plane by forcing the block 2 against the stop element 8.

Claims (11)

Conclusions. Sensor device for detecting an abnormal state of a scrap ribbon in a weaving machine comprising a block (2) with a guide element (3) for the scrap ribbon, wherein in a normal state of the scrap ribbon the block (2) is in a nominal position and wherein the block (2) is slidably mounted along a trajectory of the scrap ribbon so that the block (2) can be shifted from its nominal position in a direction opposite to the normal direction of movement of the scrap ribbon by forces acting on the block (2) in the aforementioned direction opposite to the normal direction of movement of the waste ribbon. Sensor device according to claim 1, characterized in that a proximity sensor (9) is provided, wherein a presence or absence of the block (2) in the nominal position is detectable by the proximity sensor (9). Sensor device according to claim 1 or 2, characterized in that a guide shaft (4) is provided, in which the block (2) is mounted slidably along the guide shaft (4) on the guide shaft (4). Sensor device according to claim 3, characterized in that a mounting support (5) with two wings (6) is provided, the guide shaft (4) being mounted between the wings (6) of the mounting support (5), each wing (6 ) is provided with a guide element (7) for the waste ribbon, in particular the guide elements (7) are aligned with respect to each other along an axis which extends parallel to the guide axis (4). BE2019 / 0061 Sensor device according to claim 4, characterized in that a movement of the block (2) in the normal direction of movement of the waste ribbon towards a first wing (6) of the mounting support (5) is limited by a stop element (8). Sensor device according to any one of claims 3 to 5, characterized in that the block (2) is rotatably mounted on the guide shaft (4), a force being applied to the block (2) around the block (2) about the guide shaft (4) rotate out of the nominal position, and wherein the block (2) is held in the nominal position against the aforementioned force by a waste ribbon with a predefined tension. Sensor device according to claim 6, characterized in that the block (2) is provided with a detection plane (10), the block (2) being considered to be arranged in the nominal position as long as the detection plane (10) is within a certain area fitted. Sensor device according to claim 7, characterized in that the guide element (3) for the waste ribbon of the block (2) is a guide eye, an axis of said guide eye and a rotation axis (18) of the block (2) in a central plane ( 13) of the block (2), and wherein the detection plane (10) is arranged asymmetrically with respect to the central plane (13). Method for detecting an abnormal state of a waste ribbon at a weaving machine, wherein the waste ribbon is passed through a block (2), which block (2) is arranged slidably along a path of movement of the waste ribbon, in a normal state of the waste ribbon the block (2) in a nominal BE2019 / 0061 position, and wherein when the waste ribbon is moved in a direction opposite to its normal direction of movement, the waste ribbon exerts a force on the block (2) in said direction opposite to the normal direction of movement of the waste ribbon and the block (2 ) is moved from the nominal position in the aforementioned direction opposite to the normal direction of movement of the waste ribbon. Method according to claim 9, characterized in that a presence or absence of the block (2) in the nominal position is detected by a proximity sensor (9). Method according to claim 9 or 10, characterized in that the block (2) is arranged rotatably about an axis of rotation (18) which extends at least substantially parallel to the path of movement of the waste ribbon, a force being applied to the block (2) to rotate the block (2) about the axis of rotation (18) from the nominal position, and wherein the block (2) is held in the nominal position against the aforementioned force by a waste ribbon with a predefined tension.