DE2416075A1 - METHOD AND DEVICE FOR CONTROLLING THE THREAD TENSION IN A RUNNING THREAD - Google Patents

Description

DIPL-ING. R. MERTENS DIPL-PHYS. DR. R. KEIL

Patent attorneys ο Frankfurt / M, April 2nd, 1974

t Frankfurt / M.!, Amnwiburgstr. 34

Bleiche AG, Zofingen / Switzerland

Method and device for controlling the thread tension in a running thread

The present invention relates to a method for regulating the tensile force of a running thread, in particular on textile machines, where the thread is braked by braking devices, and on a device for carrying it out of the procedure.

To regulate the tensile force of a running thread, it can be passed through a directed air flow The dynamic pressure that builds up in the direction of flow in front of the thread is used to control the braking elements

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because the thread is deflected in the area of the air flow under its dynamic effect. With this approach it should be noted that the thickness of the running thread influences the size of the back pressure.

According to the present invention, the influence of the thread thickness to the magnitude of the dynamic pressure thereby eliminated be that the thread and at least one obstacle are arranged in a directed air flow, which obstacle · at Changes in the tensile force of the thread, which is guided over two abutments, moves in the direction of the air flow, that the movement of the obstacle changes the pressure in a pressure probe arranged in the air flow and that the pressure change the braking elements are influenced in such a way that the change in the tensile force is compensated for. One to carry out The device provided with braking elements of the method is characterized by one with a blown air source connected blown air nozzle for generating the directed air flow, by two arranged on the side of the air flow Abutment for the running thread, through one between eggs Blown air nozzle and the abutments arranged, the braking elements controlling pressure probe and by a arranged in the flow direction after the pressure probe between the latter and the abutments movably arranged obstacle.

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Based on the accompanying thematic drawings, the Invention explained for example. Show it:

Fig. 1 is a view of a first embodiment, Fig. 2 is a plan view of Fig. 1,

3 shows an enlarged detail from FIG. 1 Depiction,

Fig.'4 a section along the line IV-IV according to Fig. 3 and

FIG. 5 shows the same view as FIG. 1 of a second embodiment sb e i sp i e 1 s.

In FIGS. 1 and 2, a running thread 1 is passed through a measuring device 2 for measuring the thread tension and through a brake 3 out. This measuring device 2 has a carrier plate 4 to which a blow nozzle 5 is attached. A cover plate 6 ″ is also attached to the blower nozzle 5. The blower nozzle 5 is connected to a pipe (not shown) via a line 7 Blown air source connected. On the carrier plate are also attached symmetrically with respect to the nozzle axis zv / ei V / iderlager 8, against which the thread 1 rests. On a mounted on d.er support plate 4 axis 9 is a Hub Io rotatably mounted on which a ring segment 11 with Openings 12 is attached. The Hingsegement 11 is around Axis 9 can be swiveled. The Ringsegaent lies between the

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2 * 16075

The mouth of the blowing nozzle 5 and the running thread 1 and protrudes into the blowing air flow of the blowing air nozzle 5. Under the effect of the blown air or the dust pressure generated by it in front of the ring segment 11, the latter is pivoted about the axis 9 and pressed against the thread 1. The thread 1 is thereby deflected between the abutments 8. The air passing through the opening 12 acts directly on the thread and at the same time reduces the friction between the ring segment 11 and the running thread 1. The pressure probe 13 comprises a bore 14 acting as a sensor in the carrier plate 4, a line 15 and a pneumatic amplifier 16. The bore 14 opens between the blow nozzle 5 and the ring segment 11. The back pressure of the blown air that builds up in front of the ring segment 11 is transmitted through the bore 14 to the line 15 to the amplifier 16 where it is used to control the brake. 3, the amplifier 16 know a housing 17 with a lid 18 between which a ring frame is _t fastened 19. a ring socket 19 is an elastic Membrane 2o is held peripherally, which divides the interior of the housing 17 into a pressure chamber 21 and a ventilated chamber 22. In the housing 17, a pin 23 is mounted axially to the membrane 2o and slidably into a diametrical opening 24 in a journal attached to the housing 17 25. In the opening 24 is a with the

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Pin 23 connected bracket 26 mounted displaceably. At the
The free end is the journal 25 with a threaded hole
27 for receiving a plug screw 28 is provided. Between
A helical spring 29 is arranged on the bracket 26 and the adjusting screw 28, the preload of which can be regulated by turning the adjusting screw 28. There are two on the journal 25
Brake plates 3o and 31 are freely rotatably mounted, between which the running thread 1 is passed. The bracket 26 presses the brake plate 31 against the brake plate 3o and this against the housing 17 * so that the two brake plates exert a clamping effect on the thread 1. As can be seen from FIGS Blowing nozzle 5 facing side a cutting edge ¹¹ S ″. On the the
The side of the ring segment 5 facing away from the blow nozzle 5 is this
provided with an annular groove "F" serving as a thread guide,
which stabilizes the thread 1 against lateral displacement.

If the thread 1 runs in the direction of arrow P, the
Blow nozzle 5 blows an air stream at constant speed against the ring segment 11 and the tension of the thread 1 is low, the ring segment 11 directs the thread 1 between
the abutments 8 strong, and the back pressure in front of the
The mouth of the bore 14 falls off. As a result, the pressure in the pressure chamber 21 falls, and the pin 23 is pushed into the housing 17 under the action of the helical spring 29, with the bracket 26 pushing the brake plate 31 against the brake plate 3o
presses. As a result, the running thread 1 is braked and his

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Tension rises. With increasing tension in the thread 1 this pivots the ring segment 11 about the axis 9 against the Blowing nozzle 5. The closer the hanging segment 11 approaches the mouth of the bore 14, the greater the dynamic pressure of the blowing air in front of the ring segment 11. As a result, the pressure in the pressure chamber 21 increases and the elastic membrane 2o becomes deflects against the pin 23 and this is pushed out of the housing 17. The pin 23 is pushed out against the action of the helical spring 29 »whereby the force acting on the brake plate -31 is reduced. As a result, the braking force acting on the running thread 1 becomes smaller and its tension drops. Now the through the blow nozzle 5 exiting Blasluft.des ring segment 11 again pivot clockwise about the axis 9 and more strongly deflect the running thread 1 between the abutments 8, whereupon eich repeat the processes described.

In the exemplary embodiment according to FIG. 5, equivalent reference numbers show the same or equivalent parts as in the ^{exemplary embodiment according to FIGS. 1 and 2. Instead of a ring segment, a flag II 1} engages the openings in the jet ^{of air exiting from the air nozzle 5 1} , in contrast to the first exemplary embodiment 12 are missing.-The functional principle is otherwise exactly the same.

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Instead of a ring segment 11 or a flag 11 * can also a body between two longitudinal guides which are symmetrical to the direction of the blown air and can be displaced longitudinally in the blown air flow be stored by the tension in the running thread 1 on the one hand and the dynamic effect of the air flow on the other hand, is kept in equilibrium.

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Claims (7)

Claims I)) Method of regulating the pulling force of a running Thread, in particular on textile machines, the thread being braked by braking elements, characterized in that that the thread and at least one obstacle are arranged in a directed air flow, which obstacle in the event of changes in the tensile force of the thread, which is guided over two abutments, it moves in the direction of the air flow moves that the movement of the obstacle increases the pressure in a pressure probe arranged in the air flow changes and that the change in pressure affects the braking elements in such a way that the change in tensile force is compensated for will. 2) Device for carrying out the method according to claim 1, with braking elements, characterized by a blown air nozzle (5, 5 ') connected to a blown air source for generating the directed air flow, through two abutments (8, 8 ¹ ) arranged on the side of the air flow for the current Thread (1, I ¹ ) through a pressure probe that controls the braking elements (3) and is arranged between the blown air nozzle (5, 5 ¹ ) and the abutments (8, 8 ¹⁾ 409881/0754 by an obstacle (11, II ¹ ) which is arranged in the direction of flow after the pressure probe (13, 14) and ^{movably arranged between this and the abutments (8, 8 f)} 3) Device for performing the method according to 'claim 2, characterized in that the obstacle (11, 11 ') is a plate protruding into the air flow, which is pivotably mounted about an axis (9, 9 ') oriented transversely to the air flow. 4) Device according to claim 3i, characterized in that that the plate has a shape that is convex towards the blown air nozzle (5 »5 '). 5) Device according to claim 4, characterized in that the plate (11) is designed as a ring segment. 6) Device according to claim 4, characterized in that the plate (11) has at least one through hole (12) is provided for the blown air. 409881/0754 »16075 7) Device according to claim 4, characterized _f in that the plate (11) on which the blowing air nozzle (5) applied side has a groove acting as a thread guide (F). 409881/0754 4 * Blank page