EP0811573A2 - Yarn feeder - Google Patents

Abstract

A thread supply unit (F) has a stationary storage drum (4) and at least one opto-electronic thread sensor (S) which comprises: at least one reflector (RF) fixed, with an exposed boundary area (19), in the drum surface (20) by a holder (H) and; an optical transmitter-receiver arrangement (7) located above the drum and directed at the reflector. The reflector with its bounding surface (19) can be set, from outside the drum, to two different levels (I, II) relative to the drum surface.

Description

The invention relates to a thread delivery device specified in the preamble of claim 1.

In a yarn delivery device known from EP-A-0 327 937 with a stationary storage drum designed as a rod cage, the reflector of the thread sensor is fixed with retaining screws in a recess in a rod of the storage drum. The reflector is located between glass or plastic plates. Fixing screws of the reflector penetrate the bottom wall of the rod and are fixed from the inside of the storage drum with retaining nuts. When processing weft threads in a thread delivery device inevitably fluff and dust occur, which have the undesirable tendency to separate and adhere to the boundary surface of the reflector. This deteriorates the optical transmission properties and affects the sensitivity of the thread sensor. In order to achieve a self-cleaning effect due to the thread turns moving forward on the storage drum, the boundary surface is arranged in relation to the circumference of the storage drum at an altitude in which it is cleaned of the moving thread turns. In the case of other thread qualities, however, which convey lubricating or sticky material due to a pretreatment, this height position would be undesirable because the reflector is smeared or glued by this material. Therefore, the boundary surface of the reflector is then brought to a lower altitude so that it is no longer touched by the thread. For this purpose, the washers provided for the first-mentioned height position below the reflector are removed after removing the retaining nuts of the fastening screws for adjusting the second height position before the retaining nuts are tightened again. This change is labor-intensive and time-consuming because the storage drum must be dismantled at least to a large extent in order to gain access to the retaining nuts.

The invention has for its object to provide a yarn delivery device of the type mentioned, in which the change in the height of the boundary surface or the reflector can be made easily and conveniently in relation to the storage drum circumference.

The object is achieved with the features specified in claim 1.

In this embodiment, the storage drum no longer has to be disassembled to change the height of the boundary surface of the reflector, since no access to the interior of the storage drum is necessary to actuate the holding device. Rather, the reflector can be conveniently and quickly adjusted to the desired altitude by simply actuating the holding device from the outside at any time.

In principle, the reflector could be a reflective element. It is expedient, however, according to claim 2, to combine the reflector with a glass or plastic plate which, with regard to desirable optical properties, defines a distance between the reflector and the boarding surface and protects the reflector. The reflector could be integrated in one piece in the plate. However, it is also conceivable to cover a separate reflector through the plate to the outside.

According to claim 3, the reflector is in a recess of the storage drum. This makes it possible to create a smooth thread transport surface on the surface of the storage drum. The reflector is securely attached to the vibrations of the storage drum that are unavoidable during operation and its height can be adjusted from the outside.

A structurally simple embodiment is evident from claim 4. In one installation position, the engagement and counter-engagement elements do not interlock. The boundary surface of the reflector is, for example, approximately flush with the thread transport surface. In the other installation position, however, the engagement and counter-engagement elements engage in one another, so that the boundary surface lies below the thread transport surface.

In the embodiment according to claim 5, a simple and convenient height adjustment (possibly stepless) is possible.

In the alternative embodiment according to claim 6, the reflector is properly positioned by means of the wedge surfaces at any height (possibly infinitely adjustable). The height adjustment element simplifies the height adjustment and secures the reflector, e.g. for the transport of the thread delivery device.

A particularly convenient embodiment is set out in claim 7. Such two-position push-button systems are common and allow the reflector to either be brought into the lower, positioned altitude by pressure from the outside, or to be moved back from the lower altitude to the higher altitude.

In the alternative embodiment according to claim 8, the reflector is moved back and forth between its heights by pivoting adjustment. The boundary surface does not move parallel to itself; however, this is irrelevant for the thread sensor with a small swivel stroke.

In the alternative embodiment according to claim 9, the boundary surface of one of two reflectors arranged in mirror image is brought into the desired height by rotating the reflector about the axis of rotation. The latching between the reflector and the recess automatically ensures proper positioning.

In view of simple handling, the embodiment according to claim 10 is useful. The support into which the reflector is either inserted from above or inserted from the side can be e.g. as a molded plastic part with the desired shape. In this reflector unit, the reflector itself can be a simple plate or a strip which is fixed in the carrier to which the holding device engages.

In the alternative embodiment according to claim 11, the reflector without the aid of a tool by pressing and moving between the two Adjusted altitude. The respective positioning takes place by means of the guide elements and, if necessary, supported by the spring element.

The embodiment according to claim 12 is expedient because the spring element fulfills a double function by, on the one hand, biasing the reflector outwards and, on the other hand, filling in the dimensional difference, so that no dirt, dust or fluff penetrate into the recess.

In order to be able to align a different reflection area or a reflector with only a limited reflection area in the respective installation position of the carrier on the light source and receiver arrangement, the embodiment according to claim 13 is expedient. This also allows the reflector to be replaced.

According to claim 14, the retaining screw additionally secures the reflector, e.g. for transport or against loosening due to operational vibrations.

In the embodiment according to claim 15, the holding device for adjusting the height or fixing the reflector after turning the storage drum is easily accessible from the outside.

In the embodiment according to claim 16, the reflector required in each case is aligned with the light source receiver arrangement by rotating the storage drum. This change in altitude can also be carried out from the outside and without the aid of a tool.

Fig. 1

schematisch eine Seitenansicht eines Fadenliefergeräts,

Fig.2A-D

Schnittansichten einer ersten Ausführungsform mit zwei unterschiedlichen Höhenlagen der Begrenzungsfläche des Reflektors, wobei die Fig. 2C und 2D Schnitte in den Ebenen III-III bzw. IV-IV in den Fig. 2A und 2B sind,

Fig. 3

einen Längsschnitt einer weiteren Ausführungsform,

Fig. 4

einen Längsschnitt einer weiteren Ausführungsform,

Fig. 5

einen Querschnitt einer weiteren Ausführungsform,

Fig. 6

einen Längs- bzw. Querschnitt einer weiteren Ausführungsform,

Fig. 7

einen Längsschnitt einer weiteren Ausführungsform,

Fig. 8

einen Längsschnitt einer weiteren Ausführungsform, und

Fig. 9

einen Querschnitt einer weiteren Ausführungsform.

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

Fig. 1

schematically a side view of a thread delivery device,

Fig. 2A-D

Sectional views of a first embodiment with two different heights of the boundary surface of the reflector, FIGS. 2C and 2D being sections in planes III-III and IV-IV in FIGS. 2A and 2B,

Fig. 3

2 shows a longitudinal section of a further embodiment,

Fig. 4

2 shows a longitudinal section of a further embodiment,

Fig. 5

3 shows a cross section of a further embodiment,

Fig. 6

2 shows a longitudinal or cross section of a further embodiment,

Fig. 7

2 shows a longitudinal section of a further embodiment,

Fig. 8

a longitudinal section of a further embodiment, and

Fig. 9

a cross section of a further embodiment.

A thread delivery device F according to FIG. 1, which is usually used for supplying a loom with weft thread, has in a housing 1 a rotary drive 2 for a winding element 3 with which a thread drawn from the left in FIG. 1 from a supply spool (not shown) Y is temporarily stored in turns on a stationary storage drum 4. The weaving machine, not shown, intermittently draws off weft sections depending on the pattern. The rotary drive 2 supplements the weft thread supply on the storage drum 4 in order to maintain a sufficient and predetermined supply size. At least one thread sensor S optoelectronically scans the size of the thread supply and supplies signals to a control device C which switches on, accelerates, decelerates or switches off the rotary drive 2. The thread sensor S has a light source and receiver arrangement 7 arranged in a cantilever 5 of the housing 1 and a reflector RF arranged on the storage drum 4. The storage drum 4 is prevented from rotating, for example, by cooperating permanent magnets 9, but is relative in individual steps when a sufficiently large torque is applied rotatable to the housing 1. The thread delivery device F can also have more than one optoelectronic thread sensor, for example also a thread break sensor or a winding take-off sensor (each with a reflector and a light source and receiver arrangement).

The reflector RF is fixed in the storage drum 4 by means of a holding device H and can be adjusted (arrow 8) from the outside at different heights with respect to the surface of the storage drum. For this purpose, the storage drum 4 is expediently rotated about the storage drum axis until the holding device H has emerged from the covering area of the cantilever 5 in order to actuate the holding device comfortably and without dismantling the storage drum 4 from the outside. The storage drum 4 usually consists of individual circumferentially spaced segments or rods which define a thread transport and storage area. Frequently, the storage drum 4 is designed as a so-called rod cage with stationary rods spaced apart in the circumferential direction and rods lying between them and relatively movable for the purpose of feed and thread separation. The reflector RF is then expediently in one of the stationary rods.

2A to 2C in a first embodiment the reflector RF is sunk in a rod R of the storage drum and by means of the holding device H at two different heights I and II (I: FIGS. 2A, 2C; II: FIG. 2B, 2D) adjustable. In the vertical position I, there is a boundary surface of the reflector F at a distance X below the adjacent peripheral surface 20 of the rod R. In the vertical position 2, the boundary surface 19 lies approximately flush with the adjacent receiving surface 20.

In the embodiment shown, the reflector RF is combined with a plastic or glass plate 10, for example applied to its underside, which defines the boundary surface 19 with its top. In detail, the reflector can have, for example, strip-shaped reflective regions 11a with intervening, non-reflective strip-shaped regions 11b, so that - seen over the length of the plate 10 - there is only a limited reflection region 11. The entire underside of the plate 10 could also be a reflection area 11. The reflection area 11 can be also arrange inside the plate 10. Furthermore, it is conceivable to arrange the reflection area 11 on its own reflector element, which lies below the plate 10 and is covered by it.

The reflector RF, the plate 10 with the reflection area 11 and a frame-like or C-shaped support 12 form a reflector unit in the embodiment shown, which is positioned by means of the holding device H in a recess 13 of the rod R which is open to the outside. The recess 13 has at one end a nose 14 with an adjoining inclined surface 14a which merges into the base 15 of the recess 13. At the other end of the recess 13, an externally releasable retaining screw 16 is provided which engages over a fork-like projection 17 of the carrier 12. A similar fork-like projection 17 is provided at the other end of the carrier 12. The carrier 12 can be used in two installation positions rotated by 180 ° with respect to one another. At least one engagement element E, for example a depression, is formed in the base 15 of the recess 13. At least one counter-engagement element G, for example a projection, is formed on the underside of the carrier 12. In the case shown, two engagement elements E and two counter-engagement elements G are provided, which are matched in size, shape and in their relative positions to one another such that in the high position I the counter-engagement elements G engage in the engagement elements E and the underside of the carrier 12 on the bottom 15 rests. In the elevation II, the reflector unit or the carrier is rotated by 180 °, so that the counter-engagement elements G rest on the base 15 and no longer engage in the engagement elements E. The boundary surface 19 is then in the vertical position I. The C-shaped support 12 is open at the side, so that the plate 10 can be pushed out laterally after removal of the support 12 and, if necessary, exchanged or rotated through 180 °, even in the rotated installation position of the carrier 12 according to FIG. 2B to position the reflection region 11 again in alignment with the light source and receiver arrangement 7. The plate 10 is removably held by edge regions 18 of the carrier 12. If a reflection region 11 is provided over the length of the plate 10, the plate 10 need not be removed and rotated when the carrier 12 is rotated.

In the embodiment according to Fig. 3, the holding device H for the reflector RF consists of at least two height adjustment elements 21, e.g. Screws or bayonet elements which can be screwed into threaded bores 22 (which can be open laterally towards the interior of the recess 13), protrude laterally therefrom and engage stops 23 of the carrier 12. For example, spring elements 24 are provided below the reflector RF and hold the stops 23 in contact with the height adjustment elements 21. The height of the boundary surface 19 can be changed continuously.

In the embodiment according to FIG. 4, the holding device H enables the height to be changed without the aid of tools by simple pressure with the fingers. The reflector RF with its support 12 is at least shorter in the axial direction than the recess 13. The spring element 24 located below the support 12 can be, for example, a rubber, elastomer or foam member 25 which acts on the reflector RF upwards and has an end part 25 'expediently extends to the upper edge of the recess 13. In lateral pockets 25 of the carrier 12, guide members 26 are formed on the carrier, which interact with stops 27 and 28 on the inner wall of the recess 13. In Fig. 4 the altitude II is set. The boundary surface 19 is approximately flush with the circumferential surface of the rod R. The carrier 12 is pressed to the left by the spring element 24 in FIG. 4. The guide members 26 are positioned between the projections 27 and 28 or pressed against the projections 27 from below by the spring element 24. The distance between the right end of the carrier 12 in FIG. 4 and the inner wall of the recess 23 is dimensioned so large that the guide members 26 are pulled away from the projections 28 by moving the reflector RF in FIG. 4 to the right, by increased finger pressure from the outside down under the projections 28 and then moved by the pressure of the end portion 25 'or by moving to the left under the projections 28. Then the altitude I (not shown) is set. To remove (and insert) the reflector RF, the guide members 26 are pushed past the projections 27 to the right, then the spring element 24 automatically pushes the reflector RF out of the recess 13.

In the embodiment according to FIG. 5 (cross section through the rod R), the reflector unit RF consists of the support 12 and two plates 10 arranged in mirror image with two (not shown) reflection areas (or of a single plate 10 and an inner reflection area reflecting on both sides). The carrier 12 is rotatable about an axis of rotation 27 in the recess 13 by at least 180 ° (arrow). The axis of rotation 27 is arranged with respect to the boundary surfaces so that the height distance of one boundary surface from the axis of rotation 27 is different than the height distance of the other boundary surface from the axis of rotation 27. Depending on the rotational position of the carrier 12, the altitude I or the altitude II is set. Latches 28 between the carrier 12 and the inner walls of the recess 13 position the reflector RF in the selected height.

In FIG. 6, the reflector RF is designed in the manner of a two-position push button that can be locked in two different heights, and can be released and locked in by pressure from the outside. Detachable and automatically engaging locking mechanisms 29 are provided between the carrier 12 and the recess 13 by pressure from the outside from above. If necessary, the spring element 24 is inserted below the reflector RF. However, it is also conceivable to place the reflector RF directly at the base 15 of the recess 13 at the height I.

In FIG. 7, an extension 31 is formed on the carrier 12 of the reflector RF, which defines a pivot axis 31 with an abutment in the recess 13 at a distance from one end. In the other end of the bracket 12 is a height adjustment element 16, e.g. a screw or a bayonet rotating element, which engages in the bottom of the recess 13. In order to set the altitude I, the height adjustment element 16 is adjusted downwards. The reflector pivots down with its boundary surface 19 over its entire length. If appropriate, the spring element 24 is inserted into the recess 13.

8, the carrier 12 of the reflector RF has a wedge-shaped nose 34 at one end, which cooperates with an oblique wedge surface 33 of the recess 13. In the other end of the recess 13, a parallel wedge surface 32 is provided, on which either a wedge surface or an edge of the carrier 12 can be supported. The height adjustment element 16 moves the carrier 12 parallel to itself along the wedge surfaces 33, 32 when screwing in. The carrier 12 is stably supported at any height.

In Fig. 9 in two circumferentially spaced stationary rods R (between which there are the rods R1 movable for thread separation or advancement of the thread windings) reflectors RF and RF1 are arranged so that their boundary surfaces with respect to the peripheral surfaces of the stationary rods R are at different altitudes I, II. By rotating the storage drum 4 about the storage drum axis against the holding force of the device 9, one of the reflectors RF or RF1 can optionally be aligned with the light source and receiver arrangement 7 of the sensor S in the arm 5.

In all of the embodiments shown and described, the height of the boundary surface of the reflector with respect to the adjacent peripheral surface of the storage drum can be adjusted from the outside without disassembling the storage drum, in conjunction with a rotation of the storage drum relative to the extension arm 5, either to access the To win holding device H from the outside, or to align one of several reflectors optionally to the light source and receiver arrangement 7.

Claims (16)

Thread delivery device (F) with a stationary storage drum (4) and at least one opto-electronic thread sensor (S), which has at least one in the storage drum surface (20), an externally exposed boundary surface (19), with a holding device (H) has a fixed reflector (RF) and a light source and receiver arrangement (7) arranged outside the storage drum (4) and aligned with the reflector (RF), the reflector (RF) with its boundary surface (19) with respect to the surface (20 ) of the storage drum (4) can be positioned at different heights (I, II), characterized in that the holding device (H) for positioning the reflector (RF) can be actuated from the outside of the storage drum (4). Thread delivery device according to claim 1, characterized in that the reflector (RF) is combined with a glass or plastic plate (10) defining the boundary surface (19). Thread delivery device according to claim 1, characterized in that the reflector (RF) is positioned by means of the holding device (H) in an outwardly open recess (13) in the surface (20) of the storage drum (4), preferably in a rod (R) the storage drum designed as a bar drum. Thread delivery device according to claim 3, characterized in that at least one engagement and one counter-engagement element (G, E) are provided on the reflector (RF) and / or in the recess (13), that the reflector (RF) from the outside in at least two different Installation positions (I, II) can be inserted into the recess (13), and that the engagement and counter-engagement elements (G, E) are coordinated in shape, size and relative positions in such a way that they are at a lower height (I) of the reflector ( RF) interlock. Yarn feeding device according to at least one of claims 1 to 3, characterized in that the height of the reflector (RF) in the recess (13) by at least one height adjustment element (21, 16), preferably a screw or a, accessible from outside the storage drum (4) Bayonet rotating element, is adjustable. Thread delivery device according to at least one of Claims 1 to 3 and 5, characterized in that wedge surfaces (32, 33, 34) are arranged on the reflector (RF) and / or in the recess (13) and are relative to the immersion direction of the reflector (RF) are inclined in the recess (13), and that, preferably, at least one externally operable height adjustment element (16) is provided for changing the immersion depth of the reflector (RF). Thread delivery device according to at least one of claims 1 to 3, characterized in that the reflector (RF) in the recess (13) is adjustable in the manner of a two-position push button by pressure from the outside between latched or positioned height positions (I, II). Thread delivery device according to at least one of claims 1 to 3, characterized in that the reflector (RF) is held in the recess (13) so as to be adjustable about a pivot axis (31) and can be pivoted from the outside about the pivot axis (31) between vertical positions (I, II) is. Thread delivery device according to at least one of claims 1 to 3, characterized in that the reflector (RF) in the recess (13) about an axis of rotation (27), preferably an axial axis of rotation, at least 180 ° between two different heights, and, preferably , can be locked at any height, and comprises two reflectors arranged in mirror image or a double-sided reflector, which are arranged in relation to the axis of rotation (27) in such a way that the two outer boundary surfaces (19) have different distances from each other the axis of rotation (27). Thread delivery device according to at least one of Claims 1 to 9, characterized in that the reflector (RF) or the two reflectors arranged in mirror image form a reflector unit with a preferably frame-like or C-shaped support (12), and in that the reflector unit by means of the holding device (H) can be positioned relative to the storage drum surface (20) at different heights of the boundary surface (19) of the reflector (RF) pointing outwards. Thread delivery device according to claim 10, characterized in that the reflector (RF) is adjustable against the elastic resistance of at least one spring element (24, 25) arranged in the recess (13) by pressure and displacement from the outside into the different height positions (I, II) , and that mutually engageable guide elements (26, 27, 28) are provided on the reflector (RF) and in the recess (13) for the respective positioning. Thread delivery device according to claim 11, characterized in that the recess (13) is dimensioned larger than the reflector outline, and that at least one rubber or foam member (25, 25 ') designed as a spring element (24) and filler body in the recess (13 ) is provided, which fills out the dimensional difference elastically compliant to the outside. Thread delivery device according to claims 2 and 10, characterized in that the reflector (RF) or the plate (10) in the carrier (12) can be removed or is arranged in its holding position in the carrier (13). Thread delivery device according to at least one of the preceding claims, characterized in that the reflector (RF) is additionally secured in position at the respective height (I, II) by an externally releasable retaining screw (16). Thread delivery device according to at least one of the preceding claims, characterized in that the light source and receiver arrangement (7) in a stationary arm which runs along the outside of the storage drum (4) at a distance (5) is arranged such that the storage drum (4) can be held stationary relative to the extension arm (5) by means of a device (9) which generates a predetermined rotational resistance, and that the holding device (H) of the reflector (RF) can be rotated by rotating the storage drum (4 ) around the storage drum axis and relative to the boom (5) for actuation from the boom area. Thread delivery device according to at least one of the preceding claims, characterized in that in the storage drum (4) a first reflector (RF) with its boundary surface (19) at a first height (I) and at least one second reflector (RF1) with its boundary surface (19 ) at a second height (I) and offset to the first in the circumferential direction of the storage drum (4), and that by rotating the storage drum (4) about the storage drum axis, each reflector (RF, RF1) can be aligned with the light sources and receiver arrangement ( 7) can be positioned in the boom.

Images