EP1154946A1

EP1154946A1 - Device and method for the selective braking of a running thread

Info

Publication number: EP1154946A1
Application number: EP00907612A
Authority: EP
Inventors: Lars Helge Gottfrid Tholander
Original assignee: Iro Patent AG
Current assignee: Iropa AG
Priority date: 1999-02-23
Filing date: 2000-02-23
Publication date: 2001-11-21
Anticipated expiration: 2020-02-23
Also published as: CN1344219A; KR20010111493A; CN1159200C; US6505653B1; DE50002070D1; EP1154946B1; WO2000050326A1; SE9900665D0

Abstract

The invention relates to a device for the selective braking of a running thread (Y), comprising a controlled thread brake (1) having at least two brake elements (B, B') which can be elastically pressed against each other with an adjustable force that determines the braking effect. The thread (Y) runs between said brake elements. The device further comprises an actuator for the temporary passivation of the braking effect, a control device (C) to which the first actuator (M1) is connected and a device for adjusting the brake force. According to the invention the adjustment device is actuated by means of a second actuator ( M2), which is also connected to a control device (C), only in case of a passive braking effect.

Description

Device and method for varying braking of a running thread

The invention relates to a device of the type specified in the preamble of claim 1 and a method according to the preamble of claim 13.

A controlled thread brake is expediently used in a rapier or projectile weaving machine in order to give the thread entered in the shed a specific tension profile which is important for an optimal insertion process and which varies during the insertion process. For example, in a rapier weaving machine, it is advisable to brake harder at the start of the entry, to reduce or passivate the braking effect via the subsequent acceleration phase of the rapier gripper, to brake again more strongly during the transfer phase from the rapier rapier to the slave rapier, at least to reduce the braking effect via the acceleration phase of the slave rapier or to passivate, and to brake again more strongly towards the end of the entry until the thread entered is released by the slave gripper.

In a controlled thread brake known from EP-A-0 524 429, braking is either not carried out at all or with a single braking force value set on the adjusting device. The braking force can be selected manually on the adjusting device. A change in force is not possible during an entry process because of the short time available. Since the braking force is the same for all braking phases, it represents a compromise, so that the braking effect can be too low for one operating phase and too strong for another. It is namely expedient to brake with different braking effects during different phases of an insertion process.

It is known from practice to vary the braking action in the case of a controlled thread brake with an actuator, for example a stepping motor which responds quickly, in order to take into account the requirement for different braking effects in different phases of the insertion process. Due to the extraordinarily short time span of an entry process and the function-related inertia of the update tors it takes a relatively long time until the braking effect is actually passivated or activated or until the respective force acts. Often there is an unsuitable residual braking effect when passivating or when activating the desired braking effect is not yet achieved at the required time. Overall, too much braking power is applied to the thread, or an insufficient braking effect at the required times or certain angular values of the rotation of the main shaft of the weaving machine.

The invention has for its object to provide a device of the type mentioned, with which an optimally timed thread tension profile can be generated in a structurally simple manner during each entry process, or to specify a method with which an optimal thread tension profile can be achieved with each entry process.

The object is achieved with the features in claim 1 and in method claim 13.

Since in the device the second actuator adjusts the force determining the braking action only when the braking action is passivated, the braking action required in each case is available exactly at the point in time or at the angular position of the main shaft of the weaving machine at which or at which the first actuator the braking action activated quickly. Since the time interval between two operating phases with activated braking effect can be used to vary the force, and the first actuator can activate or passivate the respective braking effect extremely quickly, an optimal tension profile of the thread can be achieved, especially by the fact that the first and second Actuators share the task of activating or passivating the braking effect and varying the force.

According to the method, it is expedient to use only operating phases with a passivated braking effect to vary the force in order not to make any disadvantageous or delayed change in the force during the operating phases requiring the full braking effect. An electrical, electromagnetic, piezoelectric, electromechanical, pneumatic or hydraulic second actuator is expediently used, which uses the times when the braking effect is passivated to change the force, while the first actuator is only responsible for the rapid activation and passivation of the braking effect

Both actuators are preferably connected to a common control device which ensures that the second actuator is only activated if the first actuator has passivated the braking effect

The second actuator can be used particularly expediently in a so-called window-disk thread brake to adjust the contact pressure of the spring disk, which works together with the abutment bolt that has the window for passivating the braking effect Abutment bolt or the first actuator with passivated or activated braking effect are known.A abutment bolt with only one peripheral window or with several peripheral windows can be used, with a first actuator that either rotates back and forth or rotates in one direction of rotation

Alternatively, the second actuator for adjusting the force when the braking effect is activated can also be used for controlled band brakes or disc brakes. The only requirement is a first actuator that can passivate and activate the braking effect set quickly enough

The spring plate is expediently arranged on a rotatably supported holder, the rotational position of which, together with the force of the spring plate, determines the force, and the second actuator is a rotary drive for the holder. The second actuator is expediently designed such that it has the rotational position corresponding to a specific force automatically stop In a simple manner, different rotational positions can be stored in the control device for the holder and can optionally be set via the second actuator. These different rotational positions represent the different forces or the variable braking effects.

Alternatively, the control device can contain a logical actuation inhibition device which prevents the second actuator from adjusting the force until the braking action is passivated by the first actuator.

Alternatively, the second actuator can be adjustable back and forth between at least two positions, which represent predetermined values or a predetermined ratio between the values of the force. Changes to the predetermined values or the relationship between the predetermined values can nevertheless be made on the control side.

It is expedient if the setting device for the force additionally has a manual actuation. Then the force can be changed by hand as with conventional window spring-disk thread brakes, but not during an entry process.

It is favorable to use a switching magnet, a rotating magnet, a permanent magnet motor, a stepper motor, a LAT electric motor (electric motor with a small angle of rotation) or a hydraulic or pneumatic motor as the second actuator. The second actuator can namely have a slower response than the first actuator because there is sufficient time available for the change in force, which is usually only relatively minor in practice, with a passivated braking effect during an entry process.

If the control device contains a microprocessor, the force determining the braking effect can also be infinitely adjusted by means of the second actuator. Embodiments of the subject matter of the invention are explained with reference to the drawing. Show it:

1 is a perspective view of a controlled thread brake in an operating position with the braking effect activated,

Fig. 2 shows a section to Fig. 1, in an operating phase with passivated braking effect and in the adjustment of the force determining the braking effect, and

Fig. 3 is a diagram of the operating behavior of the thread brake of Fig. 1 and

2 when used for a rapier weaving machine.

A controlled thread brake 1 according to FIGS. 1 and 2 has a U-shaped support frame 2, in one leg 3 of which an inlet opening 4 for a thread Y and thus in alignment with the other leg 6, a thread draw-off eye 7 are provided. The thread brake 1 is preferably arranged downstream of a thread delivery device F, which is only indicated by dashed lines, and upstream of a weaving machine W that uses the thread Y, preferably a rapier or projectile weaving machine.

A web 9 of the support frame 2 rotatably supports a mandrel-like holder 10 near the leg 3, which can be rotated by means of an adjusting device E, in the exemplary embodiment shown by a second actuator M2, which is designed as a rotary drive and positioner for the holder 10 and either is fixed to the support frame 2 or in a holder 17. Optionally, the adjusting device E is additionally equipped with a manual actuation, not shown, which makes it possible either to rotate the holder 10 relative to the second actuator M2, or to adjust the second actuator M2 with the holder 10 relative to the support frame 2.

On the holder 10, one end of a spring plate 14 made of resilient material is fixed with screws 13. The end of the spring plate 14 could also be tied in the longitudinally slotted holder 10. One for thread take-off eye 7 The facing end area of the spring plate 14 is supported on an abutment bolt 15 which is rotatable in the support frame 2 and approximately parallel to the holder 10. The spring plate 14 represents a first brake element B, while the abutment pin 15 forms a second brake element B '. The spring plate 14 rests with a certain force on the circumference of the abutment pin 15. The force can be adjusted by means of the second actuator M2 and / or, if present, by means of manual actuation of the adjusting device E. The thread Y runs with a predetermined thread path between the spring plate 14 and the abutment pin 15. The end of the spring plate 14 facing the thread take-off eyelet 7 is expediently bent, so that the thread Y in the thread brake 1 is braked by clamping essentially only in the contact area between the spring plate 14 and the abutment pin 15.

The abutment pin 15 is operatively connected to a first actuator M1, which is seated in the holder 17. The first actuator M1 is, for example, a permanent magnet motor which can be rotated gradually in one direction of rotation or rotated back and forth between two predetermined rotational positions. It is a quickly responding rotary drive for the abutment pin 15. In the embodiment shown, the range of rotation is e.g. between 90 and 180 °.

The abutment pin 15 is provided with a cross-section-reducing window 19 on part of its circumference. Axially on both sides of the window 19, the abutment pin 15 forms annular collars 20, 21 with a cross section, which serve as support surfaces for the spring plate 14. 1 and 2, the window 19 is formed by a reduction in cross-section of the abutment bolt 15 with a convex bottom 22 and linear or rounded transitions 23 into the peripheral surface extending over approximately 90 ° in the circumferential length.

The weaving machine W is equipped with a control unit CU, with which the thread entry is controlled. The control unit CU, in turn, is connected, possibly via a further electronic control device C, to the first actuator M1, which forms a rotary drive for the abutment pin 15, and also to the second actuator M2, which has a remote-controlled adjustment device E for the holder 10 or forms the force with which the two brake elements B, B 'are pressed against each other resiliently.

The force with which the spring plate 14 presses against the abutment pin 15 can be varied by means of the second actuator M2, and likewise via the expediently common control device C. On the control side, care is taken that actuation of the second actuator M2 is at least essentially exclusively then takes place when the first actuator M1 has rotated the abutment pin 15 into the rotational position of FIG. 2 and has passivated the braking action. In Fig. 1, the braking effect is activated and as high as is set by the second actuator M2.

If it is necessary to switch between two operating phases of the thread brake 1 with the braking effect activated, i.e. then passivated braking action to change the braking action determining force, this is done by turning the holder 10 in the rotational position of the abutment pin 15 of Fig. 2, in which the thread Y window 19 runs practically unchecked or with very low braking action, and the Spring plate 14 is supported on the ring bundles 20, 21.

The force could also be changed by a transverse displacement of the holder 10 in the support frame 2, specifically by means of a second actuator M2, which then represents a displacement drive.

The window spring disk brake shown in FIGS. 1 and 2 is only one non-limiting example of a controlled thread brake. The functional principle of changing the force with which two brake elements are pressed against one another during an insertion process is generally expedient for thread brake types in which the braking action can be quickly activated and passivated by means of a first actuator, so that the second actuator in operating phases with a passivated brake - Effect has enough time to change the force even during the same entry process. This means that the concept according to the invention can also be used for disc brakes, band brakes or also for multi-disc brakes, in which the first actuator quickly switches the braking effect on and off, while the second actuator changes the force which determines the particular braking effect.

In Fig. 1 it is indicated that the control device C for positioning or activating the braking effect on the first actuator M1 gives commands i- or i +, on the other hand, control commands (-) or (+) to the second actuator M1 if the Braking force determining force is to be changed. This is expediently carried out with reference to the angle of rotation of the weaving machine, which is only indicated schematically, as indicated by the angle sign at CU.

3 is to illustrate how a specific thread tension profile is achieved by means of the controlled thread brake 1 for a rapier weaving machine W, in which the thread Y is first transported by a rapier gripper to about the middle of the shed, then transferred to the slave rapier and by the latter completely pulled through the compartment and finally released. The three hatched fields in the diagram in FIG. 3 (thread tension f over the angle of rotation from 0 to 360 ° of the weaving machine W) illustrate operating phases with activated braking effect, while the non-hatched fields in between show operating phases with passivated braking effect.

At the beginning of the entry, the second actuator M2 sets a braking effect which corresponds to a thread tension f1. The first actuator M1 received the command i- and passivated the braking effect. The thread brake 1 is in the position of FIG. 2.

At a predetermined angular position, the first actuator M1 receives the i + command, so that it activates the braking effect, which begins almost instantaneously as predetermined by the set value f1. This braking effect is used in the first hatched field until the control device C issues the i command to the first actuator M1 is given, and this passivates the braking effect practically suddenly. Already at this point in time, the second actuator M2 can receive the signal (+), so that at an angular position x1 it begins to increase the force from the value f1 to the value f2, which is reached at an angular position x2, at the latest at the angular position at which the first actuator M1 again receives the i + command for the second hatched field and reactivates the braking effect. The braking effect is then determined by the value f2, which is initially maintained until the first actuator M1 receives the i- command in a further angular position and the braking effect is suddenly passivated. At the angular position x3, the value f2 is then changed back to the value f1 (or another value) by means of the second actuator M2, so that the value f1 (or another value) is present at an angular position x4. As soon as the first actuator M1 receives the i + command again and the braking action is activated again suddenly, the braking action starts with the value f1 to generate the third hatched field, before finally the braking action is again given to the first actuator M1 by the i- command is passivated. The thread brake 1 is then ready for the next entry process, for example to start with the value f1.

FIG. 3 shows that compared to the speed with which the actuator M1 has to activate and passivate the braking effect, the actuator M2 has far more time available or can use a larger angular range than this to change the force. This makes it possible to achieve a relatively optimal tension profile in the thread Y without doing any special control-related effort for the second actuator M2.

In a project weaving machine, a different tension profile than that shown in FIG. 3, for example for a rapier weaving machine, could be required. But even with a projectile weaving machine there are operating phases during each entry process or weaving machine cycle (at least one operating phase) in which the braking effect is passivated. The force that determines the braking action is then adjusted as soon as the first actuator M1 reactivates the braking action. It is advisable to change the force after passivating the braking effect and before reactivating the braking effect. However, it is also conceivable to have these two adjustments superimposed on one another in order to generate a voltage profile in which the plateaus of the hatched fields of the activated braking effect are less pronounced or nonexistent.

For most applications, it will be sufficient to set two different forces with the second actuator M2 or to switch back and forth between these two forces. However, it is also possible to use the second actuator M2 to continuously generate certain curve profiles which are superimposed on the curve profile generated by the first actuator. The setting of the respective force can be carried out by the control device C alone. However, it is also conceivable to use the manual actuation of the adjusting device to make certain basic settings. That means, by means of the second actuator M2, all necessary adjustments are made on the control side, or only switching operations are carried out, while basic settings e.g. done manually.

Claims

claims

1. Device for varying braking of a running thread (Y), in particular controlled thread brake (1) for a weaving machine (W) such as a rapier or projectile weaving machine, with at least two brake elements (B, B ') that can be resiliently pressed together with an adjustable force that determines the braking effect. ), between which the thread (Y) passes, a first actuator (M1) for temporarily passivating the braking effect, a control device (C) to which the first actuator is connected, and an adjusting device for the force, characterized in that the adjusting device can be actuated by means of a second actuator (M2), also connected to a control device (C), only when the braking effect is passivated by the first actuator (M1).

2. Device according to claim 1, characterized by an electrical, electromagnetic, piezo-electrical, electromechanical, pneumatic or hydraulic second actuator (M2).

3. Device according to claim 1, characterized in that both actuators (M1, M2) are connected to a common control device (C).

4. The device according to claim 1, characterized in that the braking elements (B, B ') are a spring plate (14) and by means of the first actuator (M1) rotatable abutment bolt (15) for the spring plate (14) that the abutment bolt ( 15) has at least one peripheral window (19) which passivates the braking effect in the rotational position of the abutment bolt (15) facing the window of the spring plate, and that the second actuator (M2) engages the adjusting device (E) of the spring plate (14).

5. The device according to claim 4, characterized in that the Federiamelle (14) is arranged on a rotatably supported holder (10), the rotational position of which determines the force and that the second actuator (M2) is a rotary drive for the holder (10).

6. The device according to claim 1, characterized in that in the control device (C) for the holder (10) different rotational positions are stored and can be optionally set via the second actuator (M2).

7. The device according to claim 1, characterized in that the control device (C) has a logical actuation inhibiting device for the second actuator (M2), such that the second actuator (M2) can only be actuated with the first actuator (M1 ).

8. The device according to claim 1, characterized in that the second actuator (M2) between at least two positions (+ and -) is adjustable back and forth, which represent predetermined values or a predetermined ratio between the values of the force.

9. The device according to claim 1, characterized in that the setting device (E) additionally has a manual actuation.

10. The device according to claim 1, characterized in that the second actuator (M2) is a switching magnet, a permanent magnet motor, a rotary magnet, a stepper motor, a LAT electric motor or a pneumatic or hydraulic motor.

11. The device according to claim 1, characterized in that the second actuator (M2) has a slower response than the first actuator (M1).

12. The device according to claim 1, characterized in that the force determining the braking effect can be adjusted by means of the second actuator (M2) only with a passivated braking effect and continuously.

13. A method for varying braking of a thread (Y) running to a weaving machine such as a rapier or projectile weaving machine during a thread insertion process and in a controlled thread brake (1), the thread brake (1) has at least two brake elements (B, B ') with adjustable force that determines the braking effect, between which the thread passes, and wherein the thread brake has a first actuator (M1) for passivating the braking effect and an adjusting device (E) for the force, and wherein in the method the braking effect is passivated and reactivated at least once during a thread insertion process, characterized in that the force determining the braking effect is adjusted by means of a second actuator (M2) and only when the braking effect is passivated.