DE19543229A1 - Monitor for high stretch yarns - Google Patents

Abstract

The yarn monitor, for mechanical monitoring of high stretch yarns and very fine separate filaments, has a swing body on a twin mounting to monitor the reassertion force. The swing body triggers a unit, without contact, to give an electrical switch action. Preferably the swing body is of wire bent into shape with a yarn scanning section and connecting pieces (1.2) of the same length at both ends, in a U- or trapezoid-shape, extending to the arc-shaped mounting points (1.3). They continue into wire sections (1.4) at a length and angle to the connecting piece (1.2) to deflect the scanning section against the axis in balance through the mounting point and the centre of gravity of the swing body. One of the two wire sections (1.4) indicates the position of the monitor. The wire for the monitor is of spring steel. The swing body lies on recesses cut out of thin plate strips, to form the mounting points (1.3). The plates are fitted into recesses in the housing (3), held in place by a cover (4). The position of the monitor is registered by a fork light barrier. The swing body is protected from contact by a housing, on all sides.

Description

Thread breaks in textile machines are recorded according to the known state of the art either electro-optically using fork or reflex light barriers, mechanically using Sensing lever, or capacitive using the cargo changes on the surface of fast moving textiles Threads. When monitoring highly elastic yarns, finer Single threads or low thread speeds fail these guards either completely, or they let themselves be manufacture only at high cost, so that an economical Monitoring of several thousand threads on a textile machine work facility is excluded.

With electro-optical guards, for example, are special constructional and circuitry measures required, to detect thin and often even translucent threads to be able to. The guards sensing the thread with a lever in contrast, can be inexpensive in large quantities manufacture, however, they are not sensitive enough to turn on Thread forces of less than 0.1 cN can always be reliably applied speak. Such an application is already on the order of magnitude and the considerable spread of the frictional forces of the commercially available guards usual lever bearings opposite. A particular disadvantage is that the off steering the lever by spring force, or in some Cases also with the force of a permanent magnet. With these means, forces below 0.1 cN can only be with considerable constructional and manufacturing expenditure achieve with the consequence that high manufacturing costs arise. To reduce the force at the point of the thread sensing requires a relatively long lever arm, which changes its weight and moment of inertia elevated. A high weight of the lever, in turn, increases the frictional force in the lever bearing. And the higher carrier moment also deteriorates the reaction time of the thread guardian.  

On the above factors, which is a minor thread opposing sensing force with standard guards, comes the influence of the actual electrical contact donor. The contactor is required to get one optical or acoustic signaling device, or a thread holder magnet to operate, or a thread drive motor to be able to switch. Purely mechanical switch contacts are required a certain amount of pressure to ensure safe contact guarantee. Switch independently of external forces the magnetically actuable reeds from reed relays require a weight-increasing duration on the sensing lever magnets.

The thread monitor according to the invention according to the claims 1-6 now has the advantage that the sole use of the driving force of a commuting suspended thread sensing element, already with a short Pendulum length, high sensitivity to the smallest Thread forces can be reached.

This is initially due to the fact that the return driving force of a pendulum at small deflection angles is always considerably smaller than the weight of the swinging body itself.

Furthermore, with a pendulum hanging thread sensing element the frictional forces of the bearings without great cost, be kept negligibly small with the advantage that a short pendulum length and therefore a low weight is made possible. This is advantageously achieved with storage on two cutting edges so that the thread sensor element can only deflect in one plane. The thread feel In this case, element forms with the two connections piece a U-shape to the bearing points. This design the swinging body also has the advantage that the  Thread run freely between the two bearing points can be done.

The use of the driving force to sense the thread also has the advantage that their deviations in corresponding design extremely small ge can be held. So the weight is under in one made of wire by bending made the pendulum very low because of changes only due to dimensional deviations in diameter and Total length of the wire and these two Dimensions can be kept inexpensively within narrow tolerances.

Advantageously, the two verbs are extended an additional mass is added after the storage locations, which causes a shift in the center of gravity so that the thread sensing element in the state of equilibrium from the vertical is pivoted out through the bearing leading axis. With appropriate dimensioning of the additional mass can with a thread moving vertically downwards, no twisting torque on the thread friction force because the friction force lack of a lever arm without another force component in Rich direction of the sensing element only in the perpendicular through the Bearing leading axis acts. Influencing the back driving force of the pendulum body by the thread friction is excluded.

A corresponding design of the additional mass as a switch flag or switch carrier also offers the Possibility to use an electro-optical contactor because it is inside a guard housing housed and thus largely from dust and others Environmental influences can be protected. For example a fork light barrier with integrated switching amplifier or if necessary a switching threshold is used be without further electronic circuit measures to compensate for increasing pollution  become agile. Likewise, there are no special optical dimensions took to beam bundling required because the switching object can be designed accordingly wide and also is not translucent. Such fork light barriers are extremely inexpensive available because they are large Numbers used in office equipment.

The thread monitor according to the invention according to the claims 7-10 also has the advantage that the pendulum body in essence except in the thread sensing element Housing moves. Direct contact with the pendulum body when the thread is inserted by the operating personnel not possible and damage due to deformation largely excluded.

Furthermore, the deflection of the pendulum body is limited at locations which are in the vicinity of the bearing point, so that direct contact of the thread sensing element with the housing parts is not possible. This arrangement of the impacts prevents the restoring force against any significant attraction forces of the thread sensing element and the housing wall. Such tightening forces can arise from wetting the thread sensing element with finishing agents in direct contact with the housing. By positioning the stops near the bearing points, these contact points are largely protected by the surrounding housing from being wetted with these emulsions, which usually consist of soaps, oils or fats. In addition, the tightening forces are reduced to a considerable extent due to the lower lever arm on which they can now act
In order to compensate for tolerances of the thread running plane in the textile machine, an additional thread guiding element is advantageous, which is to be arranged in the thread running direction at a short distance parallel in front of the thread sensing element. This guide element also enables the monitoring of a thread that runs at an angle to the vertical. Because the thread guide element is in this case wrapped according to the angle and this creates frictional forces, it should consist of a wear-resistant material. The thread guide element thus prevents forces acting on the thread sensing element which is greater than the restoring force of the pendulum body. After this force is less than 0.5 cN there is no great thread friction force, so that additional wear protection measures on this moving part can be dispensed with.

The thread monitor according to the invention according to the claims 11-13 also has the advantage that a protective bar limits the thread path at the ends of the thread sensing element. A thread that is in the sensing level performs a charging movement without that the thread detects from the thread at large charging angles element slips. The protective bar also prevents in Direct contact between the bearing points of the thread with the housing. Therefore can be used as housing material instead of a zinc or aluminum die-cast alloy inexpensive thermoplastic used will.

The elastic properties of a made of wire Protection bars can also be used as a clamp connection, so that further costs can be saved, because on one Screw connection can be dispensed with.

An embodiment of the invention is in the drawing shown and in the following description explained.

Show it:

Fig. 1 shows a thread monitor in section through the bearing point of the pendulum body in the "yarn breakage",

Fig. 2 shows a thread monitor in the section at the location of the yarn path,

Fig. 3 is a thread monitor in front view,

Figure 4 is a thread monitor in section through the bearing point of the pendulum body. Housing in the assembly position,

Fig. 5 shows an enlarged detail of the top view of the bearing point of the pendulum body.

The force of a thread ( 8 ) deflects the thread sensing element ( 1.1 ) of a pendulum body ( 1 ) until the connector ( 1.2 ) just comes into contact with the stop ( 4.1 ). The direction of the thread ( 8 ) is determined by a second point of contact on the thread guide element ( 6 ). The thread ( 8 ) can usually continue straight in the direction of these two thread contact points, because the thread force is always greater than the counterforce of the thread sensing element ( 1.1 ). If necessary, however, the thread ( 8 ) on the thread guide element ( 6 ) can also be deflected to the maximum by an angle (α).

By deflecting the thread sensing element ( 1.1 ) around the bearing point ( 1.3 ), the piece of wire ( 1.4 ), which is also located on the pendulum body, is pivoted out by the same angle, so that the attached switch lug ( 1.5 ) covers the window ( 5.1 ) of a fork light barrier ( 5 ) . The photodiode of the fork light barrier ( 5 ) is thus darkened and there is no electrical voltage at its circuit output.

In the event of a thread break, the thread ( 8 ) can no longer exert any force on the thread sensing element ( 1.1 ), so that the pendulum body ( 1 ) swings back around the bearing point ( 1.3 ) into the position in which the pendulum body ( 1 ) moves in State of equilibrium. By this rotary movement around the bearing point ( 1.3 ), the switching flag ( 1.5 ) is pivoted out of the area of the window ( 5.1 ) of the fork light barrier ( 5 ), so that light can fall through the window ( 5.1 ) unhindered on the photodiode, causing the circuit an electrical voltage is applied. An overshoot of the pendulum body ( 1 ) beyond the position of equilibrium prevents a stop ( 3.2 ) against which the connecting piece ( 1.2 ) comes to rest.

At each bearing point ( 1.3 ) are parallel to the plane of the pivoting movement opposite, wedge-shaped recesses ( 3.1 ) in the housing ( 3 ) on which thin sheet metal strips ( 2 ), used as a cutting edge bearing, come to rest. The metal strips ( 2 ) have recesses ( 2.1 ) in which the pendulum body ( 1 ) can be supported. In addition, the recesses ( 2.1 ) allow guidance of the pendulum body ( 1 ), so that lateral contact with the housing ( 3 ) is not possible. The depth of the recess is dimensioned such that when the pendulum body ( 1 ) is loaded laterally due to improper handling, the same enables an inclined position, so that permanent deformations on it are largely prevented.

The fork light barrier ( 5 ) is soldered onto a small circuit board ( 9 ), which also serves as a soldering point for the stranded wires of the electrical connection of the thread monitor. In addition, the printed circuit board ( 9 ) enables further electronic components to be fitted, with which, if necessary, special circuit adaptations to the signaling devices to be actuated or the like are made possible. To position the circuit board ( 9 ) or the fork light barrier ( 5 ), the circuit board ( 9 ) is guided in groove-like recesses ( 3.3 ) of the housing ( 3 ). Likewise, the thread guide element ( 6 ) is placed in a recess ( 3.4 ) of the housing ( 3 ) and thereby positioned in its position. With the cover ( 4 ), the guide element ( 6 ), like all other parts inserted into the housing ( 3 ), is secured in its position. The housing ( 3 ) and cover ( 4 ) are held firmly together by the clamping action of the protective bracket ( 7 ), the latter itself being fixed in its position by the detents ( 3.5 ) and ( 4.2 ).

Reference list

1 pendulum body
1.1 Pendulum body section thread sensing element
1.2 Pendulum body section connecting piece
1.3 Pendulum body section bearing
1.4 Pendulum body section wire piece
1.5 switch flag on the pendulum body
2 metal strips
2.1 Recess in the sheet metal strip as a storage point
3 housing
3.1 Recess in the housing for sheet metal strip admission
3.2 Stop on the housing for the pendulum body
3.3 Cutout in the housing for the printed circuit board
3.4 Recess in the housing for the thread guide element
3.5 Latch on the housing for protective bars
4. Lid
4.1 Stop on the lid for the pendulum body
4.2 Latch on the cover for protective bars
5 fork light barrier
5.1 Fork light barrier window
6 thread guide element
7 protective bars
8 threads
9 circuit board
Thread deflection angle

Claims (13)

1. thread monitor for monitoring highly elastic yarns and very fine individual threads with mechanical sensing of the thread, characterized in that the back driving force of a double-bearing pendulum body ( 1 ) is used for sensing, the pendulum body ( 1 ) actuates a device without contact, which an electrical Gear shift triggers. 2. Thread monitor according to claim 1, characterized in that the pendulum body ( 1 ) is made of wire by means of bending and forth and contains a thread sensing element ( 1.1 ), at the two ends of which an equally long connecting piece ( 1.2 ), U or trapezoidal is arranged, which extends to the circular-shaped bearing points ( 1.3 ), in the connection of which there is a piece of wire ( 1.4 ), the length and angular position of the connecting piece ( 1.2 ) determine the extent of the deflection of the thread sensing element ( 1.1 ) with respect to the axis, which in Equilibrium state through the bearing point and the center of gravity of the pendulum body ( 1 ), one of the two wire pieces ( 1.4 ) also being used to detect the position of the thread sensing element ( 1.1 ). 3. Thread monitor according to claim 1-2, characterized in that the wire of the pendulum body ( 1 ) consists of spring steel. 4. Thread monitor according to claims 1-3, characterized in that the pendulum body ( 1 ) at the bearing points ( 1.3 ) on a thin sheet metal strip ( 2 ) in cutouts ( 2.1 ) rests in a cutting shape. 5. Thread monitor according to claim 4, characterized in that the sheet metal strips ( 2 ) in recesses ( 3.1 ) of a housing ( 3 ) are inserted and fixed in position by a cover ( 4 ). 6. Thread monitor according to claims 1-5, characterized in that the detection of the position of the pendulum body ( 1 ) with a fork light barrier ( 5 ). 7. Thread monitor according to claims 1-6, characterized in that the pendulum body ( 1 ) is substantially protected on the thread sensing element ( 1.1 ) on all sides against contact by a Ge housing ( 3 ). 8. Thread monitor according to claims 1-7, characterized in that contact of the thread sensing element ( 1.1 ) with the housing ( 3 ) is prevented by stops ( 3.2 ) in the housing ( 3 ) and stops ( 4.1 ) in the cover ( 4 ) Limit the deflection of the connecting pieces ( 1.2 ). 9. Thread monitor according to claims 1-8, characterized in that a thread guide element ( 6 ) is located in the direction of the thread movement, at a small distance parallel in front of the thread sensing element ( 1.1 ). 10. Thread monitor according to claim 9, characterized in that the thread guide element ( 6 ) consists of a wear-resistant ceramic material. 11. Thread monitor according to claims 1-10, characterized in that a protective bracket ( 7 ) limits the thread running at the two ends of the thread sensing element ( 1.1 ), so that the thread cannot touch the housing ( 3 ) during charging movements. 12. Thread monitor according to claim 11, characterized in that the protective bracket ( 7 ) serves as a connecting element for the housing ( 3 ) and the cover ( 4 ), with corresponding locking lugs ( 3.3 ) and ( 4.2 ) in the housing and cover for fixing the protective bracket ( 7 ) serve. 13. Thread monitor according to claim 11-12, characterized in that the protective bracket ( 7 ) is coated with ceramic at least in the region of the thread path.