EP0674727B1 - Weft thread regulating and measuring wheel - Google Patents

Abstract

A weft thread regulating and measuring wheel (F) has a storage drum (D) for a thread stock (7) made of tangentially wound turns from which the thread (Y) may be unwound overend in sections of a predetermined length. The storage drum (D) has an energy accumulator (S) triggerable from outside the storage drum for temporarily extending a circumferentially limited expanding body (9) located below the turns in the thread stock (7).

Description

The invention relates to a weft measuring feeder according to the preamble of claim 1 or according to the preamble of the independent claim 2.

A measuring feeder is known from EP-A-0 060 234 and EP-A-0 253 359, the storage drum of which consists of several segments separated in the circumferential direction. Some of the segments can be adjusted radially asymmetrically to the storage drum axis in order to change the circumferential length of the storage drum. The stop device contains only a single stop element, which is retractable in order to release the thread for withdrawal, and is engaged again shortly before reaching the predetermined thread length in order to measure the thread length. In the measuring feeder according to EP-A-0 253 359, an actuator for adjusting the segments is also provided during operation in order to set or readjust the correct thread length.

EP-A-0 253 359 also describes a measuring feeder whose storage drum has an unchangeable diameter and a fixed circumferential length. The stop device contains a plurality of stop elements distributed in the circumferential direction around the storage drum, which can be individually controlled via a control device in order to assemble the predetermined thread length from entire turns and from fractional turns, which can be adjusted by the circumferential spacings of the stop elements.

In the case of storage drums with an unchangeable diameter and with storage drums with an adjustable diameter, the thread length is set such that the shortening occurring due to the thread tension stored in the elastic windings is taken into account when the pulled-off thread section is relaxed is. In weft measuring feeders of a storage drum of the two types mentioned, a high speed level and / or a high thread tension occurs during mixed change weaving if, in the event of a feeder malfunction (yarn break), another feeder takes over the function of the disturbed feeder. For every type of storage drum, a high level of speed can also occur briefly when weaving patterns with blatant pattern variations. Furthermore, an influence of the diameter of the supply bobbin on the take-up tension is always noticeable, ie the thread tension increases as the bobbin diameter decreases. The higher the speed level and / or the stronger the withdrawal resistance from the supply reel compared to normal operation, the more the tension in the turns in the supply increases and the more the relaxed, relaxed thread section is shortened. Therefore, the thread length is adjusted with regard to the greatest expected shortening, in order to avoid short picks, which lead to expensive machine downtimes. However, this means a high reject due to long, free thread ends to be cut during a considerable part of the operation. In the case of a weft thread measuring feeder with a storage drum with an unchangeable diameter and several stop elements, the thread length can only be set in steps which depend on the pitch of the stop elements. The spacing between the divisions cannot be very small for constructional reasons and for reasons of cost. In some cases, the set thread length is therefore longer than actually required, which also means expensive waste of thread material.

The invention has for its object to provide a weft measuring feeder either of the type specified in the preamble of claim 1 or in the preamble of the independent claim 2, which is structurally simple and reliable, and in which the thread length is independent of the storage drum type as low as possible Loss of thread material and without risk of short weft threads can be adjusted optimally short and precisely.

The object is achieved according to the invention either with the features of claim 1 or with the features of the independent claim 2.

In the measuring feeder according to claim 1, the thread length can be adjusted optimally short and precisely by means of the radially adjustable segments, because in the case of a high thread speed level and / or a high thread pull-off tension the spreading body is temporarily and quickly extended in order to wind the threads on the storage drum for this operating condition to enlarge and thus largely compensate for the greater shortening of the thread section that is drawn off when the thread is relaxed. The design and control engineering concept of the measurement feeder remains essentially unchanged. The expansion body is extended so quickly by the energy accumulator that an immediate adaptation to the changing situation takes place. The expansion body works with its energy accumulator in addition to the diameter adjustability given per se and allows an additional, rapid increase in the thread length during operation if the danger of too short weft threads occurs with the thread length set short with regard to low rejects. A small stroke of the expansion body, which can be adjustable in advance, is sufficient. The normal diameter adjustability using the radially adjustable segments would be too sluggish for such a quick adjustment.

In the measuring feeder according to claim 2 with an unchangeable circumferential length of the storage drum, the thread length can be finer graded with the spreading body even with large spacing distances between the stop elements with the aid of the spreading body, because with the spreading body the spacing distances between at least some stop elements are increased becomes. The construction effort for modifying the storage drum is low. The expanding body is also rapidly extended at a momentary high speed level and / or with increasing thread take-off tension from the supply spool in order to enlarge the windings on the storage drum to compensate for the greater shortening to be expected when the drawn-off thread section is relaxed. The winding length is expediently increased in at least one step, specifically temporarily, ie only for the operating condition which is critical with regard to compliance with the set thread length.

A structurally simple embodiment is evident from claim 3.

The movement variants according to claim 4 lead to the same result in different ways, namely an adjustment of the winding length in the supply.

An advantageous embodiment for both types of storage drum is evident from claim 5. The energy accumulator arranged in the storage drum moves the spreading body almost abruptly into the spreading position in order to counteract a situation which is critical with regard to the thread length. In the passive position, the expansion body can be part of the circumference of the storage drum or even be set back relative to it. The spring element is supported on the arm of the storage body and can be relatively strong.

The feed element, which is wobbled relative to the storage drum, assumes a double function according to claim 6 because it uses its kinetic energy to extend and possibly reset the expansion body.

According to claim 7 permanent or switching magnets or at least one permanent magnet is used as an energy store. As a result, the expansion body moves in quickly ensures the spread position and a firm mounting of the expansion body in the spread position.

According to claim 8, the expansion body is a flap which is pivoted outward about an axis approximately parallel to the drum axis.

In the embodiment of claim 9, the trigger is actuated and actuated from the outside, and is brought into effect either between the windings or in an area outside the supply. This also takes into account the fact that because of the winding movement of the thread, the advancing thread supply and the revolving thread drawn from the outside, no direct physical access to the storage drum is possible, except for the access between two thread passages or between the relatively slowly advancing thread windings.

The reset device according to claim 10 has enough time to move the expansion body into the passive position when the critical operating situation is over. The specified drives can be precisely controlled and enable rapid and precise movements.

According to claim 11, the trigger has a double function, since it triggers and resets the expansion body.

In the case of a contactless signal transmission or in the case of contactless triggering according to claim 12, the moving thread need not be taken into account.

Fig. 1 + 2

zwei Typen von Schußfadenfournisseuren, jeweils in einer schematischen Seitenansicht,

Fig. 3

ein Detail, im Schnitt zu Fig. 1 oder Fig. 2,

Fig. 4,5,6

verschiedene Betriebsstellungen zur Fig. 3,

Fig. 7

eine Detailvariante zu Fig. 3,

Fig. 8

eine weitere Detailvariante in einem Längsschnitt durch eine Speichertrommel,

Fig. 9

eine Draufsicht zu Fig. 8,

Fig. 10 + 11

eine weitere Ausführungsvariante, jeweils in einem Längsschnitt einer Speichertrommel und in zwei Betriebsstellungen, und

Fig. 12

eine weitere Ausführungsform in einem Querschnitt einer Speichertrommel.

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

Fig. 1 + 2

two types of weft feeders, each in a schematic Side view,

Fig. 3

a detail, in section to Fig. 1 or Fig. 2,

Fig. 4,5,6

different operating positions to Fig. 3,

Fig. 7

3 shows a detailed variant of FIG. 3,

Fig. 8

another detailed variant in a longitudinal section through a storage drum,

Fig. 9

8 shows a plan view of FIG. 8,

Fig. 10 + 11

a further embodiment, each in a longitudinal section of a storage drum and in two operating positions, and

Fig. 12

a further embodiment in a cross section of a storage drum.

A weft measuring feeder F according to FIG. 1 has a housing 1 in which a drive motor 2 for a winding member 3 which can be driven to rotate and a stationary storage drum D are mounted. The storage drum D, which is designed, for example, in the manner of a rod cage, defines a peripheral surface 4, to which a stop device 5 with a stop element 6 is assigned. The stop element 6 can be adjusted between the stop position shown, in which the thread Y is prevented from being taken off and held in place, and a release position in which a portion of the thread Y can be removed in the direction of the arrow from a supply 7 consisting of windings overhead of the storage drum D. In a part of the storage drum D which is delimited in the circumferential direction, an elongated expansion body 9 is arranged which, by means of an energy accumulator S arranged in the storage drum D, moves from the passive position 9II shown in solid lines into an over the adjacent peripheral surface 4 protruding spreading position 9I is extendable to increase the length of the winding. Outside the storage drum D, a trigger 10 for triggering the energy store S or a lock 18 holding the expansion body 9 (FIG. 3) is provided.

If necessary, a reset device 11 is also provided for returning the expansion body 9 to the passive position 9II. The diameter of the storage drum D is adjustable (double arrow 12).

In the weft measuring feeder F according to FIG. 2, the motor 2 for the winding member 3 is accommodated in the housing 1. The storage drum D defines with its circumferential surface 4 a support for the turns in the supply 7, from which the thread Y can be pulled off overhead and under the stop device 5. The diameter of the storage drum D cannot be changed. In the stop device 5 in the circumferential direction of the storage drum D several stop elements 6 are contained, which can be actuated optionally. The expansion body 9 can be extended by means of the energy store S in the storage drum D into the expansion position 91, in which it protrudes over the peripheral surface 4. The expansion body 9 can be returned to the passive position 9II (shown in solid lines), in which it is flush with the peripheral surface 4 or even withdraws behind it. For example, the trigger 10 and the reset 11 are arranged on the stop device 5.

In the case of both measuring feeders F, the expansion body 9 expediently extends beyond the supply 7 on both sides in the direction of the drum axis. The trigger 10 or the reset 11 engages in the area of the supply 7, or where there is an engaged Stop element 6 of thread Y does not move, ie in FIGS. 1 and 2 near the right end of storage drum D.

3 to 12 it can be seen in detail how the expansion body 9 is integrated in the storage drum D.

According to FIG. 3, the spreading body 9 drawn in solid lines 9II in solid lines is a finger 13 of the storage drum D designed as a rod cage and is pivotably mounted on an arm 15 about a pivot axis 14 lying approximately parallel to the circumference of the storage drum D. Stops not shown may be provided, e.g. on the arm 15 to define the positions 9I and 9II of the expansion body 9. These stops are expediently adjustable.

The arm 15 reaches past the expansion body 9 with an extension 16 and contains a lock 18 with which the expansion body 9 is fixed in the passive position 9II. The energy accumulator S is a leg spring 17 on the transverse axis 14, which acts on the expansion body 9 in the direction of its expansion position 91. The lock 18 has a slide 19 loaded by a spring 20, which overlaps a counter surface 22 of the expansion body 9 with a locking lug 23 and has a release opening 21 which is accessible from outside through an opening 24 in the extension 16 and in the expansion body 9 .

The trigger 10 arranged outside the storage drum, which in the exemplary embodiment shown also serves as a reset 11, has, for example, an electromagnet 25 as the drive and, as an actuator, a pin 26 with a pressure surface 27 which acts on the opening 21 is aligned and is inserted for triggering through the opening 24 until the nose 23 slides off the counter surface 22 and the energy accumulator S moves the expansion body 9 into the expansion position 9I. In the case of the pin 26, a pressure element 28 is also provided, which according to FIGS. 4 and 5 has a lateral extension 32 and can be rotated against spring force by means of a plunger 31 via an auxiliary drive 30, for example an electromagnet. In the position shown in FIG. 3, the pin 26 can be moved up and down without the pressure element 28, since a transverse extension 29 of the pin 26 can pass through a recess 33 in the pressure element 28. If the auxiliary drive 30 is actuated and the pressure body 28 is rotated about the pin 26, the extension 29 engages the pressure body 28 in such a way that it can be placed on the expansion body 9 by means of the pin 26 in order to reset it to the passive position 9II, in which the Lock 18 takes effect automatically (Fig. 6).

In FIG. 7, the attachment and locking of the expansion body 9 corresponds to that of FIG. 3. The pin 26 is driven by an electromagnet or a pneumatic cylinder. The reset device 11 is separated from the trigger 10 and has a pneumatic cylinder 34 with a tappet 35 and a pressure plate 36 which is placed on the expansion body 9.

In the embodiment of FIGS. 8 and 9, the expansion body 9 is pivotally mounted with the transverse axis 17 on the arm 15 of the storage drum D. It can be seen that the arm 15 can be adjusted in the radial direction in order to change the drum diameter. The storage drum axis is designated 37. On a non-highlighted drive shaft of the measuring feeder, the coaxial to the axis 37, a disk-shaped feed element V is rotatably mounted, the axis of rotation 38 of which is inclined with respect to the axis 37. The feed element V is supported against rotation and performs a wobbling movement when the drive shaft rotates, which movement is used in a known manner to advance the thread turns wound on the storage drum D when the drive shaft rotates. The feed element V is used with the axial component of its wobbling movement as an energy store S for moving the expansion body 9 into the expansion position 9I. For this purpose, a coupling element 42 can be pivoted in the expansion body 9 in the manner of a two-armed lever about a transverse axis 41 against spring force from the neutral position drawn in solid lines into the coupling position drawn in broken lines, for example, by means of the pin 26 of the trigger 10. In the coupling position, the coupling element 42 abuts with a widened end part 42a against the front side 39 of the feed element, into which one end of the expansion body 9 dips into a recess 40. When the feed element V strikes the coupling element 42, the expansion body is pivoted about the transverse axis 14 into the expansion position 9I and held by a lock, not shown. The expansion body later either returns automatically to the passive position 9II or it is reset by the reset means, not shown.

In the embodiment of FIGS. 10 and 11, the expansion body 9 is accommodated in a recess 44 in the storage drum D. In the passive position 9II according to FIG. 10, it is approximately flush with the peripheral surface 4. The expansion body 9 is on an axis 45 lying approximately in the circumferential direction of the storage drum Lever mechanism 46 pivotable, which is designed as a two-armed angle lever with an arm 46a and an armature part 46b forming the second arm and is pivotable about a stationary transverse axis 46. The energy store S for extending the expansion body 9 is a stationary permanent magnet 48 which is aligned with the armature part 46c. A permanent magnet 49 is used to hold the expansion body 9 in the passive position 9II and is mounted on a release part 50, for example a release lever, so as to be pivotable about a transverse axis 51. Through an opening 52 in the storage drum D, the pin 26 can act on one end of the release part 50, which is arranged between a stop 54 and a biasing spring 55. The biasing spring 55 presses the release part 50 against the stop 54. On the release part 50, for example, a leaf spring 53 is pivotally held, which engages under the projecting end of the anchor part 46b and helps when the release part 50 is pivoted by the pin 26, the contact between the anchor part 46b and the permanent magnet 49 until the armature part 46b is suddenly attracted to the permanent magnet 48.

11, the expansion body 9 is extended into the expansion position 9I, in which it is supported with end stops 56 in the recess 44 and is held by the permanent magnet 48. The release part 50 is still pressed down by the pin 26. The leaf spring 53 is in the raised position and pushing away the armature part 46. As soon as the pin 26 is withdrawn, the release part 50 returns to the position in FIG. 10. As soon as the reset means (not shown) then pushes the expansion body 9 back, the armature part 46b detaches from the permanent magnet 48 before the permanent magnet 49 is effective.

In the embodiment according to FIG. 12, the expansion body 9 is a flap 59 which can be pivoted in a recess 57 in the storage drum D about an axis 58 lying parallel to the storage drum axis. The spring accumulator S is a prestressed spring 60. The lock 18 holds the expansion body in the passive position 9II shown in solid lines. As soon as an element 64 is adjusted via the trigger 10 (indicated by dash-dotted lines), a slide 61 carrying a nose 63 is pulled away under the expansion body 9 against the force of a spring 62. The spring 60 pivots this into the dashed spread position 9I, in which it is secured to a stop 54. The turns in the supply 7 are extended in the spread position 9I. The reset means 11 indicated by an arrow resets the flap 59, whereby it is then caught and locked by the slide 61.

It is conceivable to trigger the energy store also by contactless transmission of signals, e.g. by using a transmitter and receiver.

Claims (12)

1. A weft thread measuring feed (F), with a storage drum (D) which comprises a plurality of radially adjustable segments for varying the circumferential length and is provided for a thread supply (7) formed by tangentially wound windings, from which the thread (Y) can be drawn in overhead fashion and in successive sections of a given thread length, and with a stop device (5), which is associated with the storage drum (D) and comprises a stop element (6), for measuring the thread length, characterised in that, in addition to the radially adjustable segments, the storage drum (D) also comprises an expanding element (9), which lies beneath the windings in the supply (7), is limited in the circumferential direction to a fragment of the overall circumference, is elongated approximately parallel to the drum axis and can be temporarily extended relative to the segments from a retracted passive position (9II) into an expanding position (9I) in which it projects outwards beyond the drum circumference adjoining the expanding element (9) in the circumferential direction, and a releasable extension power store (S) is provided in the storage drum (D) for extending the expanding element (9).
2. A weft thread measuring feed (F), with a storage drum (D) having a non-variable outer diameter for a thread supply (7) which is formed by tangentially wound windings, from which the thread (Y) can be drawn in overhead fashion and in successive sections of a given thread length, and with a stop device (5), which is associated with the storage drum (D) and comprises a plurality of stop elements (6) uniformly distributed over the drum circumference for measuring the thread length, characterised in that the storage drum (D) comprises an expanding element (9), which lies beneath the windings in the supply (7), is limited in the circumferential direction to a fragment of the overall circumference, is elongated approximately parallel to the drum axis and can be temporarily extended relative to the adjacent drum circumference from a retracted passive position (9II) into an expanding position (9I) in which it projects outwards beyond the drum circumference adjoining the expanding element (9) in the circumferential direction, and a releasable extension power store (S) is provided in the storage drum (D) for extending the expanding element (9).
3. A weft thread measuring feed according to at least one of claims 1 or 2, characterised in that the storage drum (D) is constructed in the manner of a bar cage with a plurality of axial fingers (13) spaced apart in the circumferential direction, and the expanding element (9) is one of the fingers (13) or is mounted on a finger (13) or arranged between adjacent fingers (13).
4. A weft thread measuring feed according to at least one of claims 1 or 2, characterised in that the expanding element (9) can be radially displaced in a position approximately parallel to the storage drum axis or can be displaced about a pivot axis (14; 58) which extends perpendicular to its longitudinal direction or parallel to its longitudinal direction.
5. A weft thread measuring feed according to at least one of claims 1 to 4, characterised in that the expanding element (9) is mounted as an axial finger (13) of the storage drum (D) so as to be pivotable to a limited degree on a storage drum arm (15) and is prestressed in the direction of the expanding position (9I) by a spring element (17) acting as the power store (S), and an automatically engaging stop (18) is provided between the arm (15) and the expanding element (9), which is releasable against spring force and locks the expanding element (9) in the passive position (9II).
6. A weft thread measuring feed according to at least one of claims 1 to 4, characterised in that the expanding element (9) is mounted as an axial finger (13) of the storage drum (D) so as to be pivotable to a limited degree on a storage drum arm (15), the power store (S) which can be brought to act upon the expanding element (9) is a feed element (V) which can be driven so as to tumble relative to the storage drum (D), and a coupling element (42) is provided on the expanding element (9), which coupling element can be displaced against spring force into a driving position and can be acted upon in the driving position by the feed element (V) and pivots the expanding element (9) into the expanding position (9I) defined by releasable locking.
7. A weft thread measuring feed according to at least one of claims 1 to 4, characterised in that the expanding element (9) is mounted on a lever mechanism (46) so as to be displaceable substantially parallel to the storage drum axis into a recess (44) in the storage drum (D) or in a finger (13) limiting the passive and expanding position (9I, 9II) in a positive-locking manner, the power store (S) is at least one stationary permanent magnet (48) cooperating with an armature element (46b) of the lever mechanism (46), and for locking the expanding element (9) in the passive position (9II) a further, preferably displaceable permanent magnet (49) is provided, which is arranged on a trigger element (50) which can be actuated from outside the storage drum (D).
8. A weft thread measuring feed according to at least one of claims 1 to 4, characterised in that the expanding element (9) is a flap (59), which can be pivoted to a limited degree in the finger (13) or in a recess (57) of the storage drum (D) about an axis (58) approximately parallel to the drum axis under the action of the power store (S) constructed as a spring element (60), and can be secured in the passive position (9II) by a springloaded, automatically engaging stop (18) which can be released from the outside.
9. A weft thread measuring feed according to at least one of claims 1 to 8, characterised in that a trigger (10) for the power store (S) with an electromagnetic, electromotive, piezoelectric, magnetostrictive, mechanical, pneumatic or hydraulic drive (25, 34) is provided outside the storage drum (D) at a distance from the circumferential surface (4) and can preferably be actuated between feed cycles.
10. A weft thread measuring feed according to at least one of claims 1 to 9, characterised in that a restoring element (11) with an electromagnetic, electromotive, piezoelectric, magnetostrictive, mechanical, pneumatic or hydraulic drive (34, 25) is provided outside the storage drum (D) and can be brought to act at least upon the expanding element which has been extended into the expanding position (9I), or the expanding element (9) can be manually restored.
11. A weft thread measuring feed according to claims 9 and 10, characterised in that an auxiliary drive (30) is provided for the trigger (10), and the trigger (10) is additionally constructed as a restoring element (11) and can be adjusted by means of the auxiliary drive (30) between a triggering function and a restoring function.
12. A weft thread measuring feed according to one of claims 1 to 9, characterised in that the power store (S) can be triggered in a contact-free manner from outside the storage drum (D), optionally during a feed cycle, e.g. inductively, by means of a radio signal, magnetically, by infrared light or by ultrasound.

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