DE4110429A1 - Traction force measurement arrangement for circulating fibres - has force sensor with flexural journals whose bending corresponds to measurement force - Google Patents

Abstract

A traction force measurement arrangement for a processing machine for circulating fibres (2) contains a force sensor (3) with flexural journals mounted rigidly on one side with the machine's frame and carrying a cantilever fibre deflector. The journal bending is a measure of the traction force. The journal is attached to the frame via a cylindrical casing (26) with axially acting clamos. The force sensor is mounted inside the casing and protrudes beyond the end of the casing with its end carrying the deflector. USE/ADVANTAGE - E.g., for use with filaments, wires, glass fibres or narrow tapes. The technical specification for the journal mounting is kept as simple as possible and sensor variations can be accommodated.

Description

The invention relates to a tensile force measuring device according to the upper Concept of claim 1.

Such tensile force measuring devices are known. Under one thread are all the usual endless structures in the present application such as. Filaments, wires, filament bundles, glass fibers. Carbon fibers, aramid fibers, optical fibers, narrow ribbons the.

Such tensile force measurements are usually between two successive idlers, which are rigid on the machine frame sit, attached so that the thread under deflection over the Tensile force measuring device is guided. This results in a the tensile force measuring device introduced on the deflection device attacking force directed radially. It is the result from the thread tension. Such tensile force measuring devices are known in various embodiments. This execution forms differ essentially in terms of Execution of the bending pin. The bending pins are always elastic deformable spring body, whose travel depends on the respective thread tension is present.

In one embodiment, e.g. B. the resultant of the thread tensile force as shear force on the bending pin of the tensile force measuring device tion. The resulting bend is proportional to the Resulting from the thread tension, and thus a measure of the Thread tension level. Force sensors are also known per se, which have a bending pin in the form of a torsion spring. The Torsion spring is turned using a lever arm. The lever arm carries the thread deflecting device at its free end which of the thread is substantially parallel to the axial direction of the Torsion spring is guided. The resultant from the thread tensile force acts as a torsional moment on the torsion spring. The the resulting twist is proportional to the result tieren the thread tension and thus a measure of its height.

In this application, the terms bending pin and pin are used  used synonymously.

It is technically complex in the known tensile force measuring devices the absolutely rigid connection of the bending pin to the machine frame, since the bending pin due to the attachment none may be exposed to internal stresses. From this result the requirements that on the one hand the bending pin with its not clamped end must remain freely movable, and that on the other hand the high required sensor accuracy for the train force measurement of running threads a tension-free installation of the Sensors required.

The object of the invention is to reduce the technical effort for To keep the bending pin fastening as low as possible and the same timely a rigid and stress-free connection of the fastened To ensure the end of the tenon to the machine frame, with additional Lich the possibility should exist in such force sensors to be able to use different versions.

This problem is solved by the characteristic features of the Claim 1.

From the invention there is the advantage that on the Zwi circuitry of other components than the sleeve is dispensed with can be. On the other hand, the jacket sleeve creates a problem loose rigid attachment to the machine frame.

The invention has recognized that the fastening of the bending pin directly in the jacket sleeve not only cheaper than that known devices, but also more flexible is. An adaptation of the special geometries more commercially available Force sensors from different manufacturers to the respective Conditions in the machine frame can be completely omitted. Also in difficult to access places can be the invention Attach the tensile force measuring device easily because it is fine-machined of the machine frame is no longer necessary.

The invention takes advantage of the knowledge that every force sensor with bending pin without internal stress due to pressure  or as a result of an otherwise prestressed condition within the intermediate jacket sleeve can sit. This realization is made possible by the previous knowledge that only very to transmit low forces from the bending pin to the casing sleeve are, and consequently an essentially stress-free Installation of the specified bending pin end in the casing sleeve can be done.

On the other hand, the fixed clamping of the jacket sleeve may be without cause further internal tensions in this, as these not on the bending pin structurally separate from the casing sleeve can transmit.

The invention can certainly be used in force sensors different size, different dimensions, under different manufacturers or different designs.

The invention can be used in industrial applications Machines or laboratory machines.

The effort for the invention, measured by progress, low. The invention can be found at any point in the machine Stells, where the thread runs past, because they only has an extremely small footprint. In principle it is enough for the invention, a receiving hole of about the outer diameter of the Attach the casing sleeve to the machine frame. This is practical any place on the machine frame possible without additional Space requirements. The connection on the machine frame must be coherent in the sense of a rigid connection. The connection can also by a weld seam or by an adhesive layer. At the same time, the jacket sleeve can either be screwed in the machine frame can be screwed in, or by means of both inhibiting courage arranged on the side of the machine frame ternpaares be clamped against the machine frame. In this In this case it is advisable to use the outside on the sleeve thread to produce as a trapezoidal thread, since this results in the The advantage is that the thread teeth when inserting the jacket sleeve are not destroyed by the machine frame.  

Another advantage is that the bearing surface of the jacket sleeve in the machine frame is enlarged. The will be advantageous Diameter of a pointed thread by half a millimeter Removal of the teeth reduced, if necessary also step by step half a millimeter or a divisible by 0.5 knife. Then you can use a standard drill bit use for the mounting hole in the machine frame.

For installing the force sensor in the interior of the casing sleeve there are several options, one of which is gluing should be particularly emphasized. With an appropriate shape The dimensions of the glued joint can even be done with cyanoacrylate Glued-in force sensor using a suitable forcing press easily repaired without destruction and reinserted will.

A further development results from the features of claim 2.

For axially tightening the screwed-in jacket sleeve and in To a certain extent it also serves as an anti-rotation device in one version Example on the sleeve against the machine frame screwed lock nut. This is on the sleeve thread screwed against the machine frame in the sense of tension. This variant provides a precisely defined clamping condition for the sleeve. Basically, it is also possible that To cement the sleeve firmly into the thread.

Claims 3 and 4 provide further training, depending on the installation offer advantages on the machine frame. Claim 4 contains an embodiment that is to be used advantageously if the Ma Rail frame no possibility to attach an internal thread the offers. The jacket sleeve inserted through the receiving hole is in one embodiment on both sides of the machine frame braced against the machine frame with one nut each, and sits rigidly connected to the machine frame in the receiving hole. For this it is necessary that the jacket sleeve diameter ge is slightly smaller than the receiving hole inner diameter.

The advantage is the stepless axial adjustment the jacket sleeve. This ensures that the thread  steering device completely independent of the geometry of the man tel sleeve or thread pitch exactly in the thread running plane brings, and can be fixed there.

A further development results from the features of claim 6 with the advantage that in addition the setting of the tensile force measurement device according to the alignment of the measuring axis with the of the deflection geometry resulting force axis before the final fastening of the jacket sleeve to the machine frame fi can be fixed, the setting being very sensitive and therefore is precisely possible. This advantage is achieved in that over the key attack surface with the help of a setting key sels a torque is introduced into the jacket sleeve, the Positioning the jacket sleeve is done by turning the same.

It should be expressly said that the invention is not limited to in the following embodiments shown types of Force sensors with single bending beams or torsion springs should be limited, but in particular that double bending beam for installation in the casing sleeve according to the invention very much are well suited.

The invention is described below on the basis of exemplary embodiments explained.

Figs. 1-3 show a Tensile force measuring device 1 on a Bear beitungsmaschine for a running yarn 2. The Zugkraftmeßein direction consists of a force sensor 3 , which is installed in the interior of the casing sleeve 26 . The force sensor is a so-called ter radial force sensor which absorbs the radial force resulting from the thread tensile force, which is introduced into the force sensor via the thread deflection roller 4 . As a result of the absorption of the radial force, the bending pin 6 bends, which is detected by means of the strain gauges 7 .

The strain gauges are inclined at an angle of 45 degrees to the axial direction on the outer surface of the bending pin ge glued. They lie in the plane in which the pin is bent. From each end of each strain gauge, a lead 8 goes to a measuring instrument for evaluation. There the measured size is converted into a readable display of the thread tension.

The force sensor is on one side rigidly connected to the machine frame 5, and has the freely projecting bending pin 6 at its other end. A storage (not shown) for the thread deflecting roller 4 follows the bending pin.

The diameter of the bending pin is not in all representations to scale.

The force sensor 3 is a commercially available component and has a cylindrical body 10 for attachment, which takes over the function of rigidly connecting the force sensor to the machine frame. This cylindrical body is directly, essentially stress-free and rigidly fitted into the interior of the casing sleeve and firmly connected to it. In the case of FIG. 1, this is done using the locking screw 13 , in the case of FIG. 2 using the adhesive layer 14 .

The jacket sleeve has annular cross sections in those Axial planes within which it receives the force sensor.

The machine frame 5 each has a receiving hole 9 , which is used directly for receiving the jacket sleeve. On the jacket sleeve takes place by means of a rigid connection to the machine frame. This connection can be designed differently. In all cases, the jacket sleeve is clamped against the machine frame in the axial direction, namely so tight that movement of the jacket sleeve in the receiving hole is not possible. The casing sleeve is then attached to the machine frame by means of different fastening devices.

In Fig. 1, this fastening device consists of a stufenar term increase in diameter 15 , which is supported with an end face 16 on the outside of the machine frame. The inserted free end 18 of the sleeve takes a Spannmut ter 19 as an axially acting clamping device. The clamping nut is screwed onto the external thread 20 of the casing sleeve. In this way, the machine frame is firmly clamped between the end face 16 of the diameter step and the facing nut end face.

In Fig. 2, this fastening device consists of an external thread 20 on the casing sleeve, which is in engagement with an internal thread 21 of the machine frame. Basically, with this type of fastening of the casing sleeve on the machine frame, securing putty is sufficient, but here the nut 19 is engaged as an axial clamping device with the external thread 20 of the casing sleeve and clamped against the machine frame.

Fig. 3 shows a fastening device in which the diameter D of the receiving hole 9 is slightly larger than the outer diameter of the casing sleeve. This is called d.

This enables the casing sleeve to be simply pushed through the machine frame. The jacket sleeve carries an external thread 20 and receives a clamping nut 19 on both sides of the machine frame. Both nuts act as a mutually inhibiting pair of nuts and are braced against one another in the axial direction.

Still further, FIGS 1 and 2, an additional feature. Between the yarn deflection device 4 and the bending pin 6 of the force sensor forms a thickening 22, which forms an air gap with the maximum width H of the casing sleeve in the unloaded state.

This air gap width decreases during operation of the tensile force measuring device, but remains as an air gap at tensile forces at the usual height. However, if the tensile forces exceed a maximum value, the thickening serves as a limit stop 23 . This is the case if the pin is bent too far as a result of the resultant of the thread tension force pointing radially to the pin axis. This would be e.g. B. the case with impermissibly high thread tension.

The special feature is that the part 24 cooperating with the stop 23 consists of one piece with the jacket sleeve. The width of the air gap is determined by the dimension of the inside diameter of the casing sleeve in relation to the outside diameter of the thickening.

For the embodiment according to Fig. 4 applies analogously to the description of Figs. 1-3. Instead of the bending pin 6 , the torsion spring 6 'subjected to torsion is now exposed to the radially acting thread, which in this case looks out perpendicularly from the plane of the paper, resulting in tensile force. The torsion spring is axially secured by means of the shaft securing ring 25 in the jacket sleeve 26 . For reasons of symmetry, the torsion spring is in this case with its two ends rotatably mounted on one side in the Tel sleeve. Between this one-sided rigid mounting and the shaft 27 sits the torsion spring 6 ', the rotation of which is a measure of the amount of the resulting thread tension resulting. The along the spring 6 'lying axis of rotation of the torsion spring coincides with the axis of rotation of the shaft 27 . On the one hand, the shaft protrudes beyond the casing sleeve end 28 and, on the other hand, carries a capacitor plate 29 at its opposite end, which is shown rotated by 90 degrees. In reality you can see the surface of the plate and not the edge of the plate. On both sides of the capacitor plate 29 Kon further capacitor plates 29 a are arranged at a distance from the former, between which an electrical voltage is present. The electrical capacitance of the capacitor changes with the respective position of the middle movable plate 29 as a function of the respective radial force results introduced on the deflection roller 4 , and is thus a measure of the amount of the tensile force.

Fig. 5 shows an axial top view of the sleeve 26 which has two mutually parallel key surfaces 29 with respect to its central axis 28 . An associated wrench 30 sits on the key engagement surfaces and enables the derar term setting of the tensile force measuring device that the force axis F, which does not coincide with the measuring axis M in the rotational position shown, coincides with this when rotated by the angle shown by the arrow.

Claims (6)

1. tensile force measuring device on a processing machine for a running thread, with a force sensor with a bending pin, which is rigidly connected on one side to the machine frame and carries a thread deflecting device that is cantilevered on one side, and the measured variable associated with the respective thread pulling force is the bending present on the pin, characterized,
that serves to connect the pin to the machine frame a cylindri cal sleeve with mutually axially acting Spanneinrich lines on its outer jacket, and
that the force sensor for mounting within the interior of the casing sleeve is rigidly installed on one side in such a way that it projects beyond the end of a casing sleeve end with its thread deflecting device, and
that the jacket sleeve is to be fastened axially clamped in or on a receiving hole of the machine frame. 2. tensile force measuring device according to claim 1, characterized in that Receiving hole and outer jacket are equipped with a thread, and that as a clamping device against the machine frame Lock nut sits on the jacket sleeve. 3. tensile force measuring device according to claim 1, characterized in that the jacket sleeve on its facing the thread deflecting device End carries a step-like diameter increase, and that the Clamping device on the protruding through the machine frame free end of the jacket sleeve sits.   4. tensile force measuring device according to claim 1, characterized in
that the receiving hole is a through hole with a larger diameter than the outer sleeve diameter, and
that the jacket sleeve carries an external thread which projects beyond the through hole on both sides, and
that a mutually inhibiting pair of nuts on both sides of the machine frame is used for fastening ver. 5. tensile force measuring device according to one of claims 1-4, characterized in that the radial dimensions of the bending pin and the inner diameter of the Jacket sleeve are coordinated so that the maximum Bending the bending pin in the direction of loading by means of a stop is limited to the casing sleeve. 6. tensile force measuring device according to one of claims 1-5, characterized in that the outer sleeve with at least one ver in the axial direction current secant key attack surface ver is seen, preferably paired with each other Key attack surfaces are diametrically opposed.