EP1786715A1 - Thread tensioner - Google Patents

Abstract

The invention relates to a thread tensioner (B) comprising tensioning elements (E1, E2) that define a thread tensioning zone. In said tensioner, the first tensioning element (E1) rests on a stop (1) and the second tensioning element (E2) can be pressed against the first tensioning element (E1) by means of an adjustable magnetic contact force (Fm) produced by a magnetic armature (A) and a repelling magnetic actuator (M). The stop (1) is located on the opposite side of the thread tensioning zone from the first tensioning element (E1). The first tensioning element (E1) is stressed by a spring force (f2) in the direction of the second tensioning element (E2) against the stop (1). Said spring force (f2) is greater in the thread tensioning zone than the respectively adjusted maximum magnetic contact force (fm). The mass of (mE1) of the first tensioning element (E1) is smaller than the mass (mA) of the magnetic armature (A).

Description

 Thread braking device

The invention relates to a thread braking device of the type specified in the preamble of patent claim 1 and claim 2.

The thread braking device known from US Pat. No. 5,979,810 (DE 195 31 579 B1) has disc-shaped braking elements. The first brake element is pressed against the stationary stop by the second brake element with the adjustable magnetic contact force. The repelling magnet is arranged on the rear side of the second brake element facing away from the first brake element and acts on the magnet armature arranged in the second brake element. The magnetic contact force can be changed continuously and continuously with the thread running. In the event of a thickening or knotting in the thread, the mass of the second brake element together with the mass of the magnet armature and against the repelling magnetic force of the magnet must be pressed away from the first brake element supported on the stationary stop. Due to the inertia of the large mass, especially the magnetic armature, there is a momentary increase in thread tension, which can lead to the thread breaking.

In the thread braking device known from US 6 161 595 A, the first braking element is provided on a stationary magnetic body. The second brake element is movable relative to the first brake element and is acted upon by a magnet with a pulling magnetic force through the first brake element. When a knot in the thread passes, the second braking element is moved away from the first braking element against the magnetic force, the gap width determining the strength of the magnetic force changing, even if the second braking element only tilts sideways. This instantaneous enlargement of the gap width significantly reduces the magnetic force, so that the braking effect is reduced and the second braking element returns to the starting position with a critical settling process after a critical settling process. With thick thread material, the reset takes place very slowly and with a clear settling.

In the thread brake device known from WO03 / 033385 A1, the first brake element is provided on a stationary magnetic body. The second brake The element is held in a self-moving manner in a hinged cover that extends over the magnetic body and is subjected to pulling magnetic force through the first brake element and pressed against the first brake element. When a thickening or knot in the thread passes, the second braking element is lifted against the pulling magnetic force, which reduces the strength of the magnetic force and changes the braking effect. In the case of thick thread material in particular, the resetting of the second braking element can be delayed after a knot or a thickening has passed, or can take place with a settling process during which the braking effect varies.

The invention has for its object to provide a thread braking device of the type mentioned, the thickening and knots in the thread can pass without danger to the thread, the braking effect does not change noticeably, and immediately sets the original braking effect after passage of the knot or thickening . The thread braking device should be particularly suitable for thick thread qualities.

According to the invention, the stated object is achieved either with the features of claim 1 or with the features of the independent claim 2.

The function of the thread braking device according to the invention takes into account the phenomenon that a knot (or a thickening) passing the thread braking zone while the thread is running at a relatively high speed produces a relatively high-frequency instantaneous energy impact transverse to the thread running direction. When the energy impact occurs, either the first brake element gives in against the spring force, while the second brake element and the mass of the magnetic armature do not respond appreciably due to inertia, or the second brake element gives in against the spring force, while the magnetic armature does not respond appreciably thanks to its large mass . In any case, it is ensured that the braking effect is not noticeably reduced when the knot passes through, because the set magnetic contact pressure or the spring force remains essentially undiminished. Furthermore, since it is still under undiminished force from the spring force, the deflected braking element returns after the knot has passed immediately and without swinging back to the starting position. With this design, the thread braking device is equally suitable for practically all thread qualities, but especially for thick thread material that generates a considerable release movement when a knot or thickening passes. The mass of the respective braking element is designed so that it can be displaced by the energy impact of the node, while the much larger mass of the magnetic armature does not move under the influence of this energy impact.

According to claim 1, the mass of the first spring element is displaced against the spring force at a node, while the magnetic armature remains at least essentially motionless with the second brake element. During normal braking of the thread without a knot or a thickening, the first spring element remains held at the stationary stop under the spring force, so that it acts like a stationary braking surface for the second braking element.

According to claim 2, the spring arrangement provided between the second brake element and the magnet armature forms a mass decoupling, so that the second brake element is displaced from a node against the spring force and relative to the magnet armature when the magnet armature remains essentially motionless.

In both cases, the previously set braking effect does not change when a node is passed. In addition, the displaced braking element returns immediately to the starting position after a knot has passed, since it may remain loaded by the increased spring force or the spring force and the set magnetic pressing force.

The thread brake is expediently a controlled leaf spring brake in which the first brake element is a leaf spring and the second brake element is a body forming a braking surface.

This could also be a different type of controlled thread brake, the first and / or second brake element of which is not based on a leaf spring, but is, for example, rigid. The leaf spring is expediently J-shaped with a freely projecting end, and is anchored with the J-hook to a preferably rotatably adjustable abutment. The spring force with which the leaf spring is pressed against the stationary stop is generated by the abutment, so that the leaf spring behaves like a stationary braking surface during normal braking operation or does not significantly leave the stationary stop even with the maximum magnetic contact pressure set. By means of a rotatably adjustable abutment, for example, the effective spring force can be adjusted as required.

The second braking element is expediently a U-shaped body, which can be rigid or resilient, e.g. a leaf spring body which is movably held in a guide in the direction of the adjustable magnetic contact force. The guide positions the body relative to the leaf spring and so that the set magnetic contact force comes into effect in the braking zone as desired. In addition, the guide can permit easy replacement of the second brake element.

In an expedient embodiment, the leaf spring (first braking element) is at least wider in the area of the stationary stop than the body forming the braking surface (second braking element). The leaf spring is supported on the stationary stop with the edge regions projecting laterally over the body.

The repelling magnetic actuator expediently has a proportional electromagnetic coil which is connected to a current control. In this way, it is possible to adjust the braking force of the magnetic armature, for example a permanent magnet, extremely quickly and sensitively, for example when using the thread braking device between a thread delivery device and a defenseless weaving machine in which relatively high thread speeds occur and as uniform as possible Thread tension is desired, which may have to be changed several times within one entry process. The magnetic contact force depends directly on the strength of the current applied to the coil. In one embodiment, stable support of the leaf spring is achieved by providing ribs on both sides of the body for both edge regions of the leaf spring.

In a particularly expedient embodiment, two thread braking devices are arranged on a common carrier, essentially mirror images of one another, preferably with an offset in the thread running direction. This thread braking device is compact and can be used to process two threads running close to one another. Nevertheless, each thread brake device can be controlled individually.

In a structurally simple, functionally reliable and compact embodiment, the body forming the braking surface is arranged on a plate, preferably with the interposition of a resilient member, and the plate is coupled via a connection to the magnetic armature, preferably a permanent magnet. The magnet armature is guided together with the plate in an axial guide, so that the magnet armature transmits the magnetic contact force in a smoothly movable manner and the plate acts on the second brake element in a centered manner.

In a preferred embodiment, the axial guide is held in a housing of the magnetic actuator.

The ribs defining the stationary stop for the first braking element can also be expediently arranged on the housing, preferably even in one piece.

The connection, which takes over the guiding task and the power transmission, has a guide body on which the plate is held via a tensioning element and an axially and radially compressed O-ring. The guide body can offer a long guide surface for axial guidance. The compressed O-ring centers and provides a desirable elasticity in the connection. Since such a braking device expediently works with a low basic braking effect when the coil is not energized, it is expedient to place a stationary auxiliary magnet in alignment and at an axial distance from the magnet armature, which has an opposite polarity to the polarity of the magnet armature , and the magnetic valve is permanently repelled. Instead of such a permanent magnet, a light spring, which can be adjustable, could alternatively be provided.

Embodiments of the subject matter of the invention are explained with the aid of the drawings. Show it:

1 schematically shows a first embodiment of a thread braking device, with normal thread running,

2 shows the braking device of FIG. 1 when a knot in the thread passes,

3 schematically shows another embodiment of a thread braking device, with normal thread running,

4 shows the thread braking device of FIG. 3 when a knot in the thread passes,

5 shows a perspective top view of a further embodiment of a thread braking device,

6 shows an axial section through a main part of the thread braking device, for example of FIGS. 1, 2 and 5, and

7 is an exploded view of FIG. 6.

1 and 2, a thread braking device B is shown schematically in a position with normal thread running and in a position with passage through a knot in the thread. The thread brake device B has a first brake element E1, for example a leaf spring L ₁ which is pressed against a stationary stop 1 by a spring 2 or by a corresponding preload with a spring force f2. The spring 2 is supported, for example, on a stationary abutment 3. The spring force f2 is optionally adjustable. The first braking element E1 has a mass mE1.

Furthermore, the thread brake device B has a second brake element E2, which is also a body F which forms a braking surface, for example a leaf spring body F ₁ , the first and second brake elements E1, E2 being arranged relative to one another such that one is dash-dotted in the thread running direction indicated thread Y tapering inlet gap 4 leads to a braking zone between the braking elements E1, E2. The second braking element E2 is located on the side of the stop 1, but is freely movable with respect to the stationary stop 1. A magnetic armature A, which has a mass mA, is connected to the second brake element E2. The magnetic armature A is subjected to an adjustable magnetic contact force fm of a repelling magnetic actuator M and is pressed against the first brake element E1. The magnetic actuator M expediently contains a proportional electromagnetic coil which is connected to a current control CU and generates the magnetic contact force fm in accordance with the current applied. The magnet armature A is, for example, a permanent magnet, so that a repelling, linear magnet actuator M is formed.

The spring force f2 for the first braking element E1 is greater than the respectively set maximum magnetic contact force fm, at least in the braking zone. The mass mE1 of the first braking element E1 is, at least in the braking zone, smaller than the mass mA of the magnetic armature A.

During normal thread passage (FIG. 1), the thread Y is braked in the braking zone in accordance with the size of the set magnetic contact force fm, the first braking element E1 remaining at least essentially held on the stationary stop 1. If a thickening or a knot K (FIG. 2) occurs in the thread Y, then the knot K runs through the thread braking device B with the possibly relatively high running speed of the thread Y. The node K generates an energy impact that tries to move the two braking elements E1, E2 away from each other. Since the mass mA of the magnetic armature A, which acts with the set magnetic contact force fm via the second braking element E2 in the thread braking zone on the first braking element E1 and has a certain inertia, because of which the mass mA due to the energy impact is not appreciable in FIG. 2 can be shifted to the left, the first braking element E1 yields with its mass mE1, which may be significantly smaller than the mass mA, under the energy impact and against the spring force f2, because the energy impact generates a force fK directed to the right in FIG. When the node K passes through, however, the set magnetic contact force fm and also the spring force f2 continue to act, so that the braking effect does not change noticeably. As soon as the node K has passed, the low mass mE1 of the first braking element E1 immediately returns to the position of FIG. 1 under the spring force F2 and without swinging.

The embodiment of the thread braking device B shown in FIGS. 3 and 4 differs from that of FIGS. 1 and 2 in that the spring force f2 e.g. is generated by a spring arrangement 2 'between the magnet armature A and the second brake element E2, which has a mass mE2 which is significantly less than the mass mA of the magnet armature A. The spring force f2 is greater than the respectively set one maximum magnetic contact force fm. The second braking element E2 is either formed on the stationary stop 1 or is arranged there as a body F which is located on the side of the braking zone facing away from the second braking element E2. When the thread is running normally (no knot or no thickening, FIG. 3), the second brake element E2 is pressed against the first brake element E1 with the set magnetic contact force fm. The spring arrangement 2 'is not noticeably compressed, since the spring force f2 is greater than the respectively set maximum magnetic contact force fm. The braking effect is dependent on the energization of the solenoid.

As soon as a knot K occurs in the thread Y (FIG. 4), the mass mE2 of the second braking element E2 becomes relative to the movement that is essentially due to the inertia mass mA of the magnetic armature that remains free and is shifted to the left against the spring force f2 by the force fK arising from the energy impact in order to let the node K pass. The magnetic contact force fm acts unchanged, and thanks to the compression of the spring arrangement 2 'an even slightly higher spring force f2, so that the set braking effect does not change significantly despite the knot K. As soon as the node K has passed, the second braking element E2 immediately returns to the position shown in FIG. 3, namely under the forces fm and f2. There is no transient response, since the lower end of the leaf spring body F (second braking element E2) is already reset while the knot is on its way out of the thread braking device.

5 shows a specific embodiment of a thread braking device B, in which two thread braking devices, for example of the type shown in FIGS. 1 and 2, are arranged together on a carrier 5. Thread eyelets 6 are provided on the carrier 5 and basically define the thread travel paths through the two thread braking devices. Each thread braking device could also be arranged in a single arrangement on a carrier 5.

Each first braking element E1 is a leaf spring L with the shape of a J, the free end 10 of the J projecting freely, and the J hook being anchored to an abutment 8 arranged on the carrier 5 such that the first is in the respective braking zone Brake element E1 is pressed against the stationary stop 1 with the spring force f2. The spring force f2 can be set, for example, by rotating the abutment 8.

Each magnetic actuator M is contained in a housing 7, on which the stationary stop 1 is formed in the form of two ribs R. The second braking element E2 is here a U-shaped body F, e.g. from a leaf spring or possibly from rigid material that is narrower than the leaf spring L, so that the leaf spring L rests with its lateral edge regions on the ribs R.

For the second braking element E2, a movement guide 11, 12 is provided on the magnet housing 7, for example in the form of longitudinal slots 12 in the legs of the U, into which pins 11 engage. This longitudinal guidance enables mobility of the second braking element in the case of variations in the magnetic contact force and / or in the braking operation.

FIG. 6 is an axial section through the main components of the thread brake device B and FIG. 5 and FIGS. 1 and 2, while FIG. 7 is an associated exploded view. The magnet actuator M is accommodated with the coil in the housing 7 and defines an inner channel in which the magnet armature A (a permanent magnet) can move linearly and can be acted upon to the right by the repelling magnetic force fm in FIG. 6. As an option, a stationary auxiliary permanent magnet PM can also be placed in the housing 7, which is axially aligned with the magnetic armature A and axially spaced therefrom. The auxiliary permanent magnet PM generates a weak magnetic contact force for the second braking element E2 in order to produce a basic braking effect even when the coil is not energized.

The stationary stop 1 is defined by the ribs R which are integrally formed on the magnet housing 7 and which the second braking element E2, i. take up the leaf spring body F between them without contact.

The body F forming the braking surface, here bent for example from a spring plate, rests on a plate 13, a spring-elastic member 14 possibly being interposed, which is positioned in a recess in the plate 13, such that the rear side of the body F holds the plate 13 possibly not contacted at all. The plate 13 is coupled to the magnetic armature A via a connection 15 which has clamping elements 17, 17a and a guide body 16. Between the guide body 16 and the plate 13, an axially and radially compressed O-ring 18 is provided under the action of the tensioning element 17a in order to integrate a certain elasticity in the connection 15 and to center the plate 13 cleanly and somewhat flexibly. The guide body 16 is axially guided in an axial guide 19 such that the guide body 16 guides both the magnetic armature A and the plate 13 in the axial direction. The axial guide 19 could be a plastic sleeve which is fixed in the housing 7. The body F is formed, for example, from a thin strip of spring steel of a square shape by bending in a U-shape, with a square, flat braking area on its braking side, followed by a slightly receding area Faces, and round end regions to the U-legs containing the slots 12 (Fig. 7).

The plate 13 (and / or the guide body 16) deforms the O-ring 18 with a conical or rounded bevel 13a and lies opposite the guide body 16 with an axial distance, so that a clean centering of the plate 13 is achieved, and yet a certain amount Movability of the plate 13 relative to the guide body 16 is possible.

Instead of the auxiliary permanent magnet PM, a weak spring that adjusts the basic braking effect could also be arranged in the housing 7.

Claims

Claims

1. Thread brake device (B), with first and second brake elements (E1, E2) defining a thread brake zone, of which the first brake element interacts with a stationary stop (1), and the second brake element (E2) by means of an egg ner with the second brake element (E2) connected magnetic armature (A) and a repelling magnetic actuator (M) with adjustable contact pressure (fm) against the first brake element (E1), characterized in that the stationary stop (1) on the first Brake element (E1) opposite the thread braking zone is arranged in such a way that the first braking element (E1) is loaded in the direction of the second braking element (E2) against the stationary stop (1) by a spring force (f2) which is greater than that in the braking zone each set maximum magnetic contact force (fm), and that the mass (mE1) of the first brake element (E1) is smaller than the mass (mA) of the magnet armature (A).

2. Thread brake device (B), with first and second brake elements (E1, E2) defining a thread brake zone, of which the first brake element interacts with a stationary stop (1), and the second brake element (E2) by means of an egg ner with the second brake element (E2) connected magnetic valve (A) and a repelling magnetic actuator (M) with adjustable contact pressure (fm) against the first brake element (E1), characterized in that the stationary stop (1) on the second Braking element (E2) is arranged opposite the thread braking zone and the first braking element (E1) has that the second braking element (E2) is loaded in the direction of the stationary stop (1) and against the first braking element (E1) by a spring force (f2) , which is greater in the thread braking zone than the respectively set maximum magnetic contact force (fm), that the mass (mE2) of the second braking element (E2) is smaller than the mass (mA) of the magnetic armature (A), and that a spring arrangement (2 ') generating the spring force (f2) is provided between the magnet armature (A) and the second brake element (E2) which is movable relative to the spring armature (A) relative to the magnet armature (A).

3. Thread braking device according to claim 1, characterized in that the first braking element (E1) is a leaf spring (L).

4. Thread braking device according to claim 3, characterized in that the leaf spring (L) is J-shaped and is anchored with a freely projecting end (10) with the J-hook (9) on a preferably rotatably adjustable abutment (8).

5. Thread braking device according to claim 1 or 2, characterized in that the second braking element (E2) is a preferably approximately U-shaped, a braking surface forming body (F), preferably a U-shaped spring steel strip bent in a Guide (11, 12) is at least approximately movable in the direction of the adjustable magnetic contact force (fm).

6. Thread braking device according to claim 3 or 4, characterized in that the leaf spring (L) is wider than the body (F) at least in the region of the stationary stop (1).

7. Thread braking device according to claim 1 or 2, characterized in that the repelling magnetic actuator (M) has a proportional electromagnetic coil which is connected to a current control (CU).

8. Thread braking device according to claim 3 and 4, characterized in that the stationary stop (1) on both sides of the body (F) arranged ribs (R) for both edge regions of the leaf spring (L).

9. Thread braking device according to claim 1 or 2, characterized in that on a common carrier (5) two thread braking devices (B) are essentially mirror images of one another, preferably with an offset in the thread running direction.

10. Thread braking device according to claim 3 or 4, characterized in that the body (F) rests on a plate (13), preferably with interposition of a resilient member (14) that the plate (13) is coupled via a connection (15) to the magnetic armature (A) _1, preferably a permanent magnet, and that the magnetic armature (A) and the plate (13) are guided in an axial direction ( 19) are performed.

11. Thread braking device according to claim 10, characterized in that the axial guide (19) in a housing (7) of the magnetic actuator (M) is fixed.

12. Thread braking device according to claim 8, characterized in that the ribs (R) on the housing (7), preferably in one piece, are arranged.

13. Thread braking device according to claim 10, characterized in that the connection (15) has a guide body (16) on which the plate (13) via a tensioning element (17a) and an axially and radially compressed O-ring (18) is supported and , preferably compliant, is centered.

14. Thread braking device according to claim 13, characterized in that there is an axial play between the plate (13) and the guide body (16), and that the plate (13) and / or the guide body (16) has a conical or rounded bevel ( 13a) which compresses the O-ring (18) positioned between them via the tensioning element (17a).

15. Thread braking device according to claim 11, characterized in that an auxiliary permanent magnet (PM) is positioned in the housing (7) in alignment with and at an axial distance from the magnet armature (A), which has a reverse polarity as the Permanent magnet of the magnetic armature (A).