CH679226A5 - - Google Patents

Description

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CH 679 226 A5

2nd

description

The invention relates to a thread monitor for a textile machine according to the preamble of claim 1. Such thread monitors are able to determine not only the presence of a thread, but also whether the thread is stationary or moving.

The basic principle of a thread monitor with a capacitive sensor is described, for example, in CH-A 479 478. As is known, textile threads carry electrical charges on their surface, which can arise, among other things, when they are pulled off the bobbins and due to friction on various deflecting elements. This charge, which moves in front of the capacitive sensor, is superimposed as a voltage signal on the voltage of the capacitor field of the sensor. The sensor system now uses these voltage changes to detect thread breaks, since the voltage difference is zero volts when the thread is at a standstill or when there is no longer any thread above the sensor field. The voltage difference obviously depends on various factors such as the fiber material, the thread count, the thread speed or the distance between the thread and the sensor. Fine threads have smaller surfaces and therefore less charge intensity than coarse threads. The lower the thread speed, the lower the charge strength that builds up on the thread, and with increasing distance of the thread, the charge intensity also decreases.

The thread monitors are preferably used on warping or slip gates, each spool on the gate being assigned its own thread monitor. In this case, conditions can arise in which numerous threads with different distances are passed in parallel or in a crossing manner past a sensor in one plane. However, this sensor only has to monitor the thread closest to it.

Problems can now arise with known thread monitors, in that the sensor does not respond in the event of a thread break, since the next intact thread with its charge potential influences the sensor as if the thread to be monitored were still present. It is therefore an object of the invention to provide a thread monitor of the type mentioned in the introduction, in which the sensor cannot be influenced by adjacent threads, even with relatively dense groups of threads. This object is achieved according to the invention with a thread monitor which has the features in claim 1.

The shielding element shields disturbing external charges, so that the sensor is only influenced by the charge potential of the thread to be monitored. The complete area coverage of the sensor field ensures that even with unusually high external potentials it is not possible to influence the sensor. The area of action of the sensor is spatially delimited by the shielding element.

The sensor field is preferably integrated in a thread guide plate, the shielding element being designed as a plate which is fastened to the thread guide plate. The plate enables the distance to the next thread to be passed by the thread monitor to be kept as small as possible. A shielding grid or the like could also be used instead of a plate. In any case, it is important to extend the area and cover the entire sensor field.

Particularly good results have been achieved with known, commercially available sensors if the distance between the sensor field and the shielding element is not greater than 10 mm and not less than 2 mm. If the distances are too great, the shielding effect decreases significantly. Excessive distances are also undesirable for reasons of space. On the other hand, if the spacing is too small, the thread can remain briefly on the shielding element, which can lead to an undesirable switching delay.

In order to prevent the shielding element itself from influencing the sensor incorrectly, it is preferably made of an electrically conductive material and grounded. The shielding element could also be made of a non-conductive material, e.g. be made of plastic and have an electrically conductive coating which is grounded.

In order not to hinder an observation of the thread running by the operating personnel, the shielding element can have at least one opening arranged outside the sensor field. After a thread deflection, the sensor field can be arranged on a deflection guide, the opening being located directly above the deflection guide. The deflection guide made of plastic material causes the desired charging when the thread is moved, and the opening allows an effortless observation of the thread coming from the bobbin.

An embodiment of the invention is shown in the drawings and will be described in more detail below. Show it:

1 is a side view of a warping machine,

2 is a plan view of the warping machine according to FIG. 1,

Fig. 3 shows a single bobbin with a thread monitor assigned to it in cross section and

4 shows a plan view of the thread monitor according to FIG. 3.

In the slip system 1 shown in FIGS. 1 and 2, the threads 5 are drawn off in a known manner from the spools 4 plugged into the slip gate 2 and wound up on the slip tree 6 in the slip machine 3. After the thread deflection 7, the threads 5 only pass a guide point in the area of the paper machine 3 in the paper comb 8, in that the thread assembly 9 receives the desired winding width on the paper tree 6 in the paper comb 8. Between the slip comb 8 and the slip tree 6 is the so-called

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Measuring roller 10 is arranged, which is used to measure the length of the wound thread assembly 9.

The thread deflections 7 take place on vertical profiled bars 15, which extend over the entire creel height. Each spool is assigned a thread monitor and a thread brake on these rods. As can be seen in particular from FIG. 2, the thread assembly becomes denser the closer a bobbin is to the warping machine. For example, all threads on the same floor and the same gate side are guided horizontally past the foremost spool 23 or the thread monitor assigned to it. On a higher-lying bobbin 24, numerous threads cross the thread monitor at different intervals.

As can be seen from FIG. 3, the thread coming from the bobbin 4 first arrives at a thread brake 11, which has the task of holding the thread in place when the winding process is interrupted. The movable clamping plate 13 is pressed against the fixed clamping plate 14 by means not shown in detail, so that the thread 5 is held in a taut position between the thread brake 11 and the warping machine 3 after the system has come to a standstill. The thread brake 11 is fastened to the profile 15 already mentioned, which has a U-shaped cross section.

The open side of the U-profile faces away from the spools 4 and is covered with a thread insertion plate 16 in the area of the thread deflection. This thread insertion plate projects laterally beyond the profile 15 and has an insertion slot 22 for inserting the thread 5. In addition to the electrical installations not shown here, the thread insertion plate 16 also carries the thread monitor 12 with the sensor. Between the individual thread guide plates 16, the opening of the U-shaped profile 15 is closed in a dust-tight manner with the aid of covers 21. The thread guide plates are screwed onto the profile 15 with the aid of screws 20. A deflection guide 18 made of an abrasion-resistant material serves to deflect the thread, so that the constant friction of the deflected thread does not cause any abrasion. The deflection guide is fastened to the thread guide plate 16 and has a notch for positioning and guiding the thread.

The sensor consists of a sensor block 17c which is integrated in the thread guide plate 16 and which in this way forms a sensor field 17a over which the thread 5 is passed. The actual sensor 17b can be cast in the form of an electrical conductor in the sensor block 17c. This sensor is in operative connection with electrical lines (not shown in more detail) with a signal transmitter for controlling the slip machine 3 or the thread brake 11.

A plate-shaped shielding element 27, which covers the entire sensor field 17a, is arranged approximately plane-parallel to the thread guide plate 16. The shielding element is designed as a sheet metal plate which is fixed with the aid of a screw 28. An opening 29 is arranged in the region of the deflection guide 18, which allows the thread 5 to be observed. The connection between the shielding element 27 and the thread guide plate 16 could also be designed such that the distance between the shielding element and the sensor field 17a or the sensor 17b can be set. The shielding element is grounded via the thread guide plate 16 and via the profile 15 or via a separate electrical conductor.

In Fig. 3, 5/25 denotes a broken thread, while an immediately adjacent thread 5/26 remains intact (see also Fig. 2). The thread 5/26 also passes the sensor 17b relatively close and has an electrical charge which could influence the sensor 17b in the direction of the arrow 19. However, the shielding element 27 prevents such an influence, so that if the thread 5/25 breaks or stops, the winding system is stopped immediately and the thread brake 11 closes.

The shielding element obviously does not hinder the insertion of the thread when setting up the slip gate. The type of fastening shown with the aid of the screw 28 prevents dust, fibers or dirt from getting stuck between the shielding element and the thread guide plate 16.

Claims (8)

Claims 1. thread monitor (13) for a textile machine with a sensor field (17a) arranged in the passage area of the thread (5), in which a capacitive sensor (17b) is arranged, with which electrical charges can be measured when the thread is moving, characterized in that that the sensor field (17a) is completely covered by a spaced-apart shielding element (27), the thread (5) being able to be passed between the sensor field (17a) and the shielding element (27). 2. Thread monitor according to claim 1, characterized in that the sensor field (17a) is integrated in a thread guide plate (16) and that the shielding element (27) is designed as a plate which is attached to the thread guide plate. 3. Thread monitor according to claim 1 or 2, characterized in that the distance between the sensor field (17a) and the shielding element (27) is not greater than 10 mm. 4. Thread monitor according to claim 1 or 2, characterized in that the distance between the sensor field (17a) and the shielding element (27) is not less than 2 mm. 5. Thread monitor according to one of claims 1 to 4, characterized in that the shielding element (27) is made of electrically conductive material and is grounded. 6. Thread monitor according to one of claims 1 to 4, characterized in that the shielding element (27) is provided with an electrically conductive coating which is grounded. 7. Thread monitor according to one of claims 1 to 6, characterized in that the screening element (27) has at least one opening (29) arranged outside the sensor field (17a) for monitoring the thread running. 8. thread monitor according to claim 7, thereby 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 5 CH 679 226 A5 indicates that the sensor field (17a) is arranged on a deflection guide (18) after a thread deflection and that the opening (29) is arranged above the deflection guide (18). 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th