EP0450379A2 - Spinning machine, in particular ring spinning machine - Google Patents

Abstract

In a ring spinning machine, for the conveyance of tube-journal slides (18), supporting rails (122) are arranged along the spinning-station groups (12a, 12b) and are constructionally combined with guide rails (121). Drivers (19) for the tube-journal slides (18) are guided on the guide rails (121) displaceably in the longitudinal direction of the machine. A vertical conveyor band (17) is connected to the drivers (19), so that these are taken up during the movement of the conveyor band and thereby displace the tube-journal slides (18) on the supporting rail (22). …<IMAGE>…

Description

The invention relates to a spinning machine, in particular a ring spinning machine, according to the preamble of patent claim 1.

In a known ring spinning machine of this type (GB-PS 1 168 638), the sleeve pins are attached directly to the endless conveyor designed as a horizontal conveyor belt. The endless conveyor is generally designed as a steel belt that warps as little as possible, so that the predetermined distances between the sleeve journals, which must exactly match the distances between the spinning positions, remain unchanged even when the machine is in operation for a long time.

While in the ring spinning machine according to GB-PS 1 168 638 the sleeve journals are arranged half the distance from the spinning positions in order to be able to accommodate an empty tube and a full tube (cop) of the assigned spinning position at the same time when doffing, it is also possible to use the as Belt-formed endless conveyor only to provide sleeve pins at a distance from the spinning stations, with an additional pin then having to be provided at each spinning station in order to temporarily accommodate one of the sleeves to be exchanged when changing the sleeves (US Pat. No. 3,905,184).

Furthermore, it is already known (EP-A-0 061 432) to provide an endless conveyor on each machine side of a ring spinning machine, both ends of each endless conveyor being equipped with sleeve pins, so that when a full sleeve (cops) is replaced by an empty sleeve, the full sleeve is initially used can be plugged onto an empty sleeve pin, while an empty sleeve is then removed from the sleeve pin assigned to the same spinning station of the other run and placed on the spindle of the spinning station. The sleeve pins are also used in this known ring spinning machine Connected directly to the endless conveyor via elbows.

The problem with the aforementioned ring spinning machines is, on the one hand, that the trunnions form an integral part of the endless conveyor, which is necessary because the trunnions in the sleeve changing position of the endless conveyor must be exactly aligned with the spinning station individually assigned to them. For this reason, the full sleeves (cops) at the end of the last group of spinning units must be removed from the trunnion and then reloaded, for example, onto peg trays on a winding machine. Conversely, the empty tubes, for example supplied by the winding machine, have to be placed on the trunnions at the beginning of the first spinning station group by means of special gripping and lifting devices.

It is also already known (JP-OS 57-161 134) that the peg trays used in the winding machine connected to the ring spinning machine can also be used as empty tube feed means or full tube discharge means, in that these peg trays, which generally consist of a circular disc and a central pin arranged vertically thereon to be displaced in a guide rail running around the ring spinning machine, the diameter, in particular the length, of a pin slide being slightly smaller than the distance between two adjacent spinning positions. The individual pin slides are in contact with one another and are pushed forward by exerting force on one or more pin slides, the thrust force being at least partially transmitted by the direct contact of the pin slides. A conveyor device for such trunnion slides is also known from DE-OS 35 44 560.

A disadvantage of the ring spinning machine according to JP-OS 57-161 134 is that the sleeves are not exactly in alignment with the spinning positions when a group of tenon slides with empty sleeves on one machine side has been moved in front of the assigned spinning positions. Therefore, before the sleeve can be changed, a rake must be pushed at right angles to the longitudinal axis of the spinning machine between the pin slides in the known ring spinning machine, so that the distances between the adjacent sleeve pins are exactly coordinated with the distances between adjacent spinning positions.

In a similar sleeve transport device (DE-OS 37 12 027), a reciprocating rail or the like extending along the spinning positions is used, which interacts with pin slides which can be displaced in a guide rail in such a way that these are gradually moved up to the assigned spinning position . So that the trunnion slides are exactly aligned with the assigned spinning station, they must either have a length exactly equal to the distance between the spinning stations, or there are pawl-like locking elements on the reciprocating rail, which are located exactly at the distance from the spinning stations, so that the locking elements ensure an exact alignment of the trunnion slides with the assigned spinning station even when the holding sledges are not in contact with each other.

Both the provision of a special alignment rake for the trunnion slide (JP-OS 62-191 524) and the arrangement of pawls pivotable about an axis for each trunnion slide (DE-OS 37 12 027) require complex production and a considerable space requirement. The known arrangements are also prone to failure and require maintenance.

A problem with generic spinning machines consists in guiding the conveyor belt, which is preferably designed as a steel belt, as little stretch as possible, but is flexible, along the spinning stations. It must be taken into account here that the drivers arranged on the conveyor belt must be positioned as precisely as possible relative to the spinning positions, so that the pin slides or sleeves carried by the drivers can be brought into exact alignment with the spinning positions.

For this purpose, it has already been proposed to guide the drivers on a machine-fixed guide rail in the longitudinal direction of the spinning machine in such a way that the conveyor belt connected to the drivers is in turn held in the desired vertical and horizontal position by the drivers. In particular, a tilting, fluttering or sagging of the conveyor belt is prevented in this way without having to be provided for this special guide and holding means.

A problem with generic spinning machines is now to accommodate the guide rail and the drivers as space-saving as possible without the guide of the drivers on the guide rail, which is also important for the exact positioning of the trunnion slides, being impaired.

The aim of the invention is to create a spinning machine of the type mentioned in the introduction, in which, despite the space-saving arrangement of the guide rail, exact guiding or holding of the journal slides and the conveyor belt is ensured.

To solve this problem, the characteristics of the characteristic Part of claim 1 provided. The guide projections therefore engage in the guide recesses from the front or rear and in any case not from below. It is therefore advantageous if the conveyor belt itself is unguided between the deflection rollers and the drivers take over the guidance by being positively guided in the machine longitudinal direction on a machine-fixed guide rail, with guide projections engaging in guide recesses from the front or rear.

In this way it is possible to functionally optimally arrange the guiding and counter surfaces which ensure perfect horizontal guidance of the conveyor belt, without this requiring an excessive space requirement. Another significant advantage of the arrangement according to the invention is that the guide projections can also be mounted from the side in the guide recesses if they are appropriately dimensioned. Finally, it is possible in this way to transfer the executives between the guide rail, drivers and conveyor belt in the shortest and most direct way without major force redirection.

Due to the design according to claim 2, both deflections of the conveyor belt downwards and upward-preventing guide surfaces can be accommodated in a space-saving manner, and tilting or deflections of the conveyor belt in the horizontal direction can also be avoided if the guide surfaces according to claim 3 are also curved. In this way, any movement of the conveyor belt and also the driver except in the conveying direction can be effectively avoided without requiring an excessive space for the arrangement of the guide and counter surfaces.

Also preferred is the embodiment according to claim 4, because in this way groove-like guide surfaces on the machine even in which dust, dirt or fiber fly could collect.

Due to the design according to claim 5, the guide rail can be located at the rear end of a corresponding longitudinal profile, while the guide recesses which are open to the front are located on the drivers on whose rear the conveyor belt is attached.

The assembly and disassembly of the drivers is facilitated by the embodiment according to claim 6, because this means that the drivers can be snapped or removed at any point on the guide rail. However, it is also possible for the guide projections to be located on the drivers, while the guide rail preferably has the guide recess on its rear side.

A particularly space-saving accommodation of the guide rail is guaranteed by the features of claim 8. In this way, for example, part of the substructure of the mounting rail can be designed as a guide rail, as a result of which only a minimal additional space is required.

In order to ensure a particularly favorable power transmission from the drivers to the conveyor belt and vice versa, the measures of claim 9 prove to be expedient. In this way, there is a full-area, ie also large-area contact between the conveyor belt and the drivers, which in particular also prevents bending or warping of the conveyor belt in the area of the drivers. The actual attachment is only punctiform, preferably in the middle, so that driving around the pulleys is not hindered.

For a space-saving accommodation and power transmission in the shortest possible way, the embodiment according to claim 10 is useful.

In order to avoid lateral guide means for the trunnion slides, according to a further advantageous embodiment of the invention, the drivers should be designed according to claim 11. It is particularly important that not adjacent drivers each hold a pin carriage between them, but that a separate holding arm is provided for each individual driver assigned to a specific pin carriage in addition to the actual driver finger. In this way, the drivers can be fastened independently of one another at exactly the right place on the conveyor belt, it being unnecessary to pay attention to any assignments of adjacent drivers in order to hold the trunnion slides.

Above all, the peg slides can be securely clamped in this way even when cornering in the area of the deflection rollers.

In particular due to the design according to claim 11, the sliding surface of the mounting rail can be designed according to claim 12. In this way, in particular the accumulation of dirt or fiber fly on the mounting rail is effectively avoided.

The embodiment according to claim 13 is particularly expedient for assembly and disassembly, a practical further development of this embodiment being characterized by claim 14.

The invention is described below, for example, with the aid of

Fig. 1

eine lediglich der Darstellung der grundsätzlichen Funktion dienende schematische Draufsicht einer mit einer Spulmaschine kombinierten Ringspinnmaschine mit einem um zwei auf unterschiedlichen Maschinenseiten angeordneten Spinnstellengruppen herumgeführten Endlosförderer in Form eines vertikal angeordneten flexiblen Stahlbandes,

Fig. 2

einen stark vergrößerten Schnitt senkrecht zur Maschinenlängsrichtung durch die Ringspinnmaschine nach Fig. 1 im Bereich des Förderbandes und der Tragschiene für die Zapfenschlitten, wobei eine erste Ausführungsform einer erfindungsgemäßen Führungsanordnung wiedergegeben ist,

Fig. 3

einen analogen Schnitt einer etwas abgewandelten Ausführungsform,

Fig.

4 einen analogen Schnitt einer anderen Ausführungsform,

Fig. 5

eine Draufsicht des Gegenstandes der Fig. 3 und

Fig. 6

einen Schnitt analog Fig. 2 einer weiteren Ausführungsform.

Drawing described; in this shows:

Fig. 1

2 shows a schematic top view of the basic function only, showing a ring spinning machine combined with a winding machine with an endless conveyor in the form of a vertically arranged flexible steel belt, which is guided around two spinning station groups arranged on different machine sides,

Fig. 2

1 in the region of the conveyor belt and the support rail for the trunnion slide, a first embodiment of a guide arrangement according to the invention being shown,

Fig. 3

an analog section of a slightly modified embodiment,

Fig.

4 shows an analog section of another embodiment,

Fig. 5

a plan view of the object of FIGS. 3 and

Fig. 6

a section analogous to FIG. 2 of a further embodiment.

According to FIG. 1, a ring spinning machine 27 has, on opposite machine sides, spinning station groups 12a and 12b running parallel to each other, each consisting of only schematically indicated spinning stations 11a, 11b, 11c, 11d, 11e, 11f, 11g, 11h and 11i, 11k, 11ℓ, 11m, 11n, 11o, 11p and 11q exist. The same possible distance between spinning positions is designated by 24. Further details of the ring spinning machine 27, in particular the machine heads, are not shown because the arrangements in question are customary and known. For the sake of clarity, the number of spinning stations 11 is reproduced in a greatly reduced manner.

An endless conveyor 17 in the form of a vertically running steel belt is guided around the two spinning unit groups 12a, 12b and is placed around the deflecting rollers 39, 40, 41, 42 with a vertical axis at the two ends of the spinning unit groups 12a, 12b running parallel and in alignment with one another. There are therefore two long debris extending along a respective spinning unit group 12a or 12b and two short debris of the endless conveyor 17 connecting the two spinning unit groups 12a, 12b at the ends.

On the conveyor 17, which is designed as a vertical steel belt, are aligned with the individual spinning positions 11a to 11q, drivers 19a, 19b, 19c, 19d, 19e, 19f, 19g, which extend outwards from the endless conveyor 17 and each have a driver finger 19 'extending perpendicular to the conveying direction , 19h or 19i, 19k, 19l, 19m, 19n, 19o, 19p and 19q attached. Immediately next to and below the endless conveyor 17, a horizontal support rail 22 extends in the area of the spinning station groups 12a, 12b, which is also guided around the left end of the ring spinning machine 27 parallel to the endless conveyor 17 in order to establish a transport connection between the two sides of the ring spinning machine.

On the support rail 22 are arranged one behind the other at a distance in contact with the driver fingers 19 'of the drivers 19a to 19h or 19i to 19q, the trunnion slide 18, which according to FIGS. 2 to 6 consists of a circular disc-shaped sliding body 44 and a sleeve journal 13 arranged vertically thereon consist, which are preferably made of plastic in one piece, and are preferably engaged by the drivers 19 in the region of a widened foot 13 'arranged between the sleeve pin 13 and the sliding body 44.

On both sides of the machine are shown in Fig. 1 dashed sleeve exchange devices 14, which can be designed as in classic doffers and are used to remove 11 full sleeves (cops) from the spindles of the spinning stations and instead place empty sleeves 16 on the spindles, which are by means of the endless conveyor 17 have been introduced to the individual spinning stations 11.

The deflecting rollers 41, 42 are connected to one another by a tensioning beam 47 which is movable in the direction of the double arrows in the longitudinal direction of the machine and which is set by a tensioning device 48 which is supported on the machine frame and under a pre-tensioning tensioning the endless conveyor 17.

At a suitable location e.g. A cleaning station with blowing or suction nozzles and / or brushes can be provided between the deflecting rollers 39, 40 in a manner not shown, in order to clean the carriers 19 and the conveyor belt 17 of fiber fly.

Furthermore, a cleaning element, for example in the form of a cleaning disk, can be fastened at any point on the endless conveyor 17, which is not already occupied by the driver 19, which slides along the carrier rail 22 when the endless conveyor 17 rotates and thereby cleans it. Such a cleaning element can be provided in all embodiments of the invention.

Conveyor belts 34, 35 form at the end of the spinning unit groups 12a, 12b facing away from the tensioning beam 47 Buffer sections 28, 29 are provided in alignment with the sections of the mounting rails 22 running along the spinning stations 11, to which a winding machine 26 with guide rails 30 and winding stations 31 is shown, which is only indicated schematically. The number of winding units 31 is at least one order of magnitude smaller than the number of spinning units 11.

In the area of the transition from the upper support rail 22 in FIG. 1 to the conveyor belt 34 directly adjoining the support rail 22, a deflector 36 is provided, which grasps the pin slides 18 in the region of the deflection roller 39 and separates them from the drivers 19 guided around the deflection roller 39 , so that they reach the conveyor belt 34 beginning in the region of the deflection roller 39.

In front of the lower deflection roller 40 in FIG. 1, a conveyor belt 35 is also arranged, which first leads to the slide carriage 18 equipped with empty sleeves 16 to a holding stop 37, which is briefly withdrawn by means of a drive device 50 controlled by a light barrier 49 to release the foremost journal slide 18 in each case can. The conveyor belts 34, 35 are driven in a controlled manner at times or continuously during a sleeve changing process.

At the front end of the conveyor belt 35, the carrier rail 22 assigned to the spinning group 12a connects, so that the pin carriage 18 released from the holding stop 37 and equipped with empty sleeves 16 is pushed by the conveyor belt 35 onto the stationary carrier rail 22 and is gripped there by the driver finger 45 of a driver 19 can be.

At the beginning and end of each conveyor belt 34, 35, light barriers 51, 52, 53, 54 are provided, which serve to determine the presence or absence of trunnion carriages 18 at the point in question and accordingly control the operation of the transport devices of the ring spinning machine 27 or the winding machine 26.

At the front end of the conveyor belt 34, a further mechanically retractable and extendable stop 55 is provided, which is temporarily withdrawn when the winding machine 26 has a corresponding full-sleeve requirement in order to allow a predetermined number of full-sleeves 15 to pass through to the winding machine 26.

The operation of the described combination of a ring spinning machine with a winding machine is as follows:

In the position shown in FIG. 1, in front of each spinning station 11 there is a journal slide 18 equipped with an empty sleeve 16. As soon as the sleeves arranged on the spindles of the spinning stations 11 are fully spooled with yarn, the empty sleeves 16 located on the individual journal carriages 18 are replaced by the The sleeve changing device 14 is lifted off the support pin 13, and the full sleeves (cops) 15 located on the spindles of the spinning stations are lifted off and exchanged for the empty sleeves 16. The full sleeves 15 arrive on the support pins 13 of the associated pin slides 18. For the sake of clarity, the intermediate pins required for the sleeve replacement are not shown in FIG. 1.

As soon as the exchange of full sleeves 15 and empty sleeves 16 has taken place, the spinning process on the ring spinning machine 27 is resumed, and the endless conveyor 17 is started in the direction of the arrow, whereupon the full sleeves 15 are successively pushed onto the conveyor belt 34 of the buffer zone by the deflector 36 28 are handed over. At the other end of the conveyor belt 34, the winder 30 calls the required one Number of full tubes 18 to produce the final large bobbins at the winding units 31.

From the guide rail 30 of the winding machine 26, the empty-wound empty tubes with the journal carriages 18 carrying them are placed on the conveyor belt 35 of the buffer section 29, wherein they are successively conveyed to the stop 37. In this way, as well as on the conveyor belt 34, a series of pin carriages 18 lying directly against one another is created, which represent a reserve for the transfer to the endless conveyor 17.

As soon as a driver 19 with driver finger 19 'comes into the position shown in dashed lines in FIG. 1 immediately in front of the deflection roller 40, the light barrier 49 releases the path for the foremost journal carriage 18 via the control line 49' indicated by the dashed line and the drive device 50 by the Holding stop 37 is briefly withdrawn. Thereupon, the conveyor belt 35 displaces this trunnion carriage into the position 18 'indicated by dashed lines in FIG. 1. Here the peg carriage is already on the stationary support rail 22. It now waits until the driver finger 19 'of the driver 19 grasps it and conveys it along the support rail 22 to the assigned spinning position of the spinning stations 11a to 11h or 11i to 11q.

The support rail 22 also has a lateral guide 56 in order to avoid lateral deflection of the pin slides 18.

Since the drivers 19 are positioned on the endless conveyor 17 exactly in relation to the individual spinning positions 11 in the sleeve change position shown in FIG. 1, the journal carriages 18 carried by them and thus the supporting journals 13 attached to the journal carriage 18 are also exactly closed the individual spinning stations 11 aligned. The initially non-existent alignment is produced during the transition from the conveyor belt 35 to the mounting rail 22, while it is deliberately given up again during the transition of the full sleeves 15 from the upper mounting rail 22 to the conveyor belt 34, since the cycle of the winding machine 26 is now changed again.

According to FIG. 2, a guide rail 121 with two lower surfaces 107, 108 is arranged on the machine frame 104 within an upper recess 111, which engages with a retaining projection 106 under a guide bar 105 of the machine frame 104 and is pressed into the retaining recess at 109 by a clamping bar 110 is so that it is fixed in a precisely defined position relative to the machine frame 104. The terminal block 110 is fixed to the machine frame by means of screws 112.

The guide rail 121, which is designed as a hollow profile, furthermore has a rearwardly extending guide projection 97 with upper and lower curved guide surfaces 95, 96, which are formed on vertically spaced guide beads 98, 99 which extend in the machine longitudinal direction, and is structurally combined with the top at an angle Carrier rail 22 arranged sloping towards the front, on which a pin carriage 18 is shown in dash-dotted lines, which between the pin 13 and the sliding body 44 also has a foot 13 'which is widened somewhat relative to the pin 13 and which is engaged by a driving finger 19'. The driver finger 19 'is connected via a holding arm 95 to the block-shaped driver 19 which is fastened to the vertical conveyor belt 17 with fastening means 113. From the opposite side, the foot 13 'is acted upon by a jaw 90 which, as shown in FIG. 5, is fastened to the holding arm 95 or directly to the driver 19 via a leaf spring 91; thereby the pin slides 18 are also guided laterally, and the side guide 56 is not required (FIGS. 1,6).

In its front area, the driver 19, which is preferably made of plastic, has a guide recess 103 which extends in the longitudinal direction of the machine and which is delimited at the top and bottom by mating surfaces 101, 102 which grip on correspondingly curved resilient tongues 93, 94 are formed. The guide surfaces 95, 96 are complementary to the counter surfaces 101, 102 in the manner shown in FIG. 2 rounded.

In this way, the driver 19 is aligned precisely and securely against tipping over relative to the machine frame 104 and can only be displaced in a sliding manner in the longitudinal direction of the machine, which is perpendicular to the plane of the drawing in FIG. 2. When the conveyor belt 17, which is itself guided except on the deflection rollers, perpendicular to the plane of the drawing in FIG. 2, the driver 19 is shifted accordingly and thereby slides in the longitudinal direction of the machine on the guide rail 121. The driver finger 19 'takes the pin carriage 18 with, which slides along on the mounting rail 22. The jaw 90 prevents slipping off the flat mounting rail 22.

Due to the guidance of the driver 19 on the guide rail 121, the conveyor belt 17 is also appropriately guided by the latter, for which no special guide means which act directly on it are provided.

It is particularly advantageous that the guide projection 97 with the guide surfaces 95, 96 is located below the mounting rail 22 next to the fastening points 105, 106, 107, 109. It is also expedient that the guide projection 97 approximately in is the same height as the conveyor belt 17, so that there is only a comparatively thin block of material of the driver 19 in between.

Another advantage is that the conveyor belt 17 and the surfaces 95, 96, 101, 102 are protected from fiber fly and dirt and are not touched by the traveling blower.

Fig. 3 shows a similar embodiment as Fig. 2, but the guide rail 121 is modified so that the guide projection 97 or the guide recess 103 is as vertical as possible below the point of engagement of the driver finger 19 'on the pin carriage 18. This avoids moments in the horizontal, and as a result the belt remains flat and the friction between the guide surfaces 95, 96 and the counter surfaces 101, 102 is minimal.

4 and 5 show a further implementation of the invention. The support rail 22, which here has a horizontal flat surface, is formed on a guide rail 121 designed as a hollow guide profile extending in the longitudinal direction of the machine and is fastened to the machine frame 104. The driver 19 is attached to the conveyor belt 17 by means of a screw 113 and is guided in the longitudinal direction of the machine by the engagement of a guide projection 93 in a guide recess 94 of the guide rail 121. For this purpose, guide grooves 101 ', 102' are formed in the guide recess 94 at the top and bottom, into which complementary guide ribs 98 ', 99' of the guide projection 93 engage.

A holding arm 95 extends upward from the catch 19, from which the catch finger 19 'branches off at the top, around the To reach behind the foot 13 'of the sleeve pin 13 in driving engagement. According to FIG. 5, the back of the foot 13 'touches a stop surface 19''which extends in the direction of conveyance (arrow), while a jaw 96 on the foot 13 rounded off from the driver finger 19' faces a leaf spring 91 via a leaf spring 91 'of the sleeve pin 13 engages, so that the pin slide 18 is held and guided in a resilient manner and can be removed in the direction away from the conveyor belt 17.

The driver finger 19 ', which moves the pin carriage 18 in the direction of the arrow in FIG. 5, determines the exact position of the pin carriage 18, while the jaw 96 merely serves to pin the pin 13 or the foot 13' of the pin 13 against the driver finger 19 '. and, if necessary, to hold the surface 19 ″ in contact and to make a movement of the pin carriage 18 perpendicular to the conveying direction impossible until a correspondingly strong pulling force is exerted to the front.

6, the support rail 22 is provided at the front with an upwardly angled lateral guide 56 in order to prevent the pin slides 18 from sliding sideways off the support rail 22. Therefore, the jaw 90 and the leaf spring 91 according to FIG. 5 can be dispensed with here. The support rail 22 is again structurally combined with a guide rail 121 which surrounds the vertical conveyor belt 17 by means of guide beads 98, 99 at the top and bottom with such a clear distance that there is no contact between the conveyor belt 17 and the guide rail 121. Outside, the guide beads 98.99 are again surrounded by preferably resilient tongues 93, 94 of the driver 19, which engages behind the support pin 13 with the driver finger 19 '.

From the back of the driver 19 extends with a projection 114 equipped with a hook 114 'through an opening 112 within the conveyor belt 17 in order to support the conveyor belt 17 and to guide it so that it moves without contact within the cavity 103 of the guide rail 121. A precisely positioned opening 112 is provided in the conveyor belt 17 for each driver 19.

According to FIG. 2 or 3, the support rail 23 forms a flat sliding surface, which preferably slopes away at an angle of 5-15 ° to the front. Correspondingly, the driver finger 19 'is formed obliquely, i.e. a part of the arm of the driver finger 19 runs parallel to the mounting rail 22. The front end of the driving finger 19 ', on the other hand, is preferably horizontal so that the pin carriage 18, when it rests on a horizontal sliding surface of a mounting rail 22 somewhere in the transport system, goes vertically upward from the end of the driving finger 19', which is also horizontal is guided or can not be lifted off the sliding surface.

Claims (15)

Spinning machine, in particular a ring spinning machine with at least one group (12a, 12b) of spinning stations (11a to 11h; 11i to 11q) arranged at the same distance apart, a tube changing device (14) for the simultaneous exchange of full tubes (15) spooled with yarn for empty tubes (16 ) at each spinning station (11a to 11h; 11i to 11q) and one running along the spinning stations and from one end of the spinning station group (12a, 12b) or several spinning station groups to the other, the empty tubes (16) to the spinning stations (11 ) back and the full sleeves (15) away from the spinning stations (11) conveying synchronous endless conveyor (17) on which upright sleeve pins (13) are attached at a distance from the spinning stations (11) in such a way that each one with a sleeve changing position of the endless conveyor (17) Spinning station (11) is exactly aligned with a sleeve pin (13) individually assigned to it, with a spinning station group (1 2a) or a plurality of spinning unit groups, a full-sleeve unloading station (32), to which the endless conveyor (17) feeds the full sleeves (15) from the spinning unit group (12a, 12b) or the spinning unit groups successively and preferably an empty-tube loading station (33) is provided at the same end which the endless conveyor (17) feeds the empty tubes (16) successively to the spinning unit group (12a, 12b) or to the spinning unit groups, each sleeve journal (13) being arranged on its own journal carriage (18), the length of which in the conveying direction is slightly less than the distance two adjacent spinning positions (11), each pin carriage (18) being assigned a driver (19) which is structurally separate from it but can be brought into engagement with it in a releasable manner and which is in such a position on the endless conveyor (17) is attached so that when the driver (19) is in driving engagement with the assigned pin slide (18), the sleeve pin (13) of this pin slide (18) in the sleeve change position of the endless conveyor (17) exactly with the assigned spinning position ( 11) is aligned, the trunnion slides (18) being slidably mounted on a support rail (22) which is preferably provided with a flat surface and which is fixedly attached to the machine frame (104) and is supported by the associated driver (19) on the support rail (22 ) are displaced, the endless conveyor consisting of a vertically arranged, inextensible, flexible conveyor belt (17), in particular steel belt, which is guided at the ends of a spinning group around deflection rollers (39, 40, 41, 42) with a vertical axis, and wherein the carriers (19) on a machine-fixed guide rail (121) which extends along the spinning station groups (12a, 12b) and engage in a complementary manner the guide projections (93, 97) and guide recesses (94, 103) are arranged so as to be displaceable in the longitudinal direction,
characterized,
that the guide projections (93, 97) engage from the side into the guide recesses (94, 103) which are open towards the side. Spinning machine according to Claim 1, characterized in that the guide projections (97) at the bottom and preferably also at the top preferably have guide surfaces (95, 96) at a significant vertical distance with an at least substantial horizontal component, which interact with corresponding counter surfaces (101, 102). Spinning machine according to claim 1 or 2, characterized in that the guide surfaces (95, 96) and counter surfaces (101, 102) are curved, the axes of curvature extending in the machine longitudinal direction. Spinning machine according to one of the preceding claims, characterized in that the guide projections (97) are located on the guide rail (121) and the guide recesses (103) are located on the drivers (19). Spinning machine according to claim 4, characterized in that the guide recesses (103) are open towards the front. Spinning machine according to one of claims 2 to 5, characterized in that the guide recesses (103) have resilient tongues (93, 94) at the top and / or at the bottom, on which the counter surfaces (101, 102) are formed and which from the side the guide surfaces (95.96) can be snapped on. Spinning machine according to Claim 1, characterized in that the drivers (19) attached to the conveyor belt (17) engage with a guide projection (93) in a guide recess (94) of complementary design on the guide rail (121) in the sliding fit. Spinning machine, in particular a ring spinning machine with at least one group (12a, 12b) of spinning stations (11a to 11h; 11i to 11q) arranged at the same distance apart, a tube changing device (14) for the simultaneous exchange of full tubes (15) spooled with yarn for empty tubes (16 ) at each spinning station (11a to 11h; 11i to 11q) and one running along the spinning stations and from one end of the spinning station group (12a, 12b) or several spinning station groups to the other, the empty tubes (16) to the spinning stations (11 ) back and the full sleeves (15) from the Spinning stations (11) away synchronous endless conveyor (17) on which upright sleeve pins (13) are attached at a distance from the spinning stations (11) in such a way that each sleeve (11) with a sleeve pin individually assigned to it is in the case of a sleeve change position of the endless conveyor (17) (13) is exactly aligned, with at one end of a spinning group (12a) or several spinning groups a full tube unloading station (32) to which the endless conveyor (17) feeds the full tubes (15) from the spinning group (12a, 12b) or the spinning groups and preferably at the same end an empty tube loading station (33) is provided, from which the endless conveyor (17) successively feeds the empty tubes (16) to the spinning unit group (12a, 12b) or to the spinning unit groups, each sleeve pin (13) on its own pin slide ( 18) is arranged, the length of which in the conveying direction is somewhat less than the distance between two adjacent spinning positions (11) Each peg carriage (18) is assigned a driver (19) which is structurally separate from it but can be brought into releasable driving engagement and which is attached to the endless conveyor (17) in such a position that when the driver (19) is in driving engagement with the assigned pin slide (18), the sleeve pin (13) of this pin slide (18) in the sleeve change position of the endless conveyor (17) is exactly aligned with the assigned spinning station (11), the pin slide (18) preferably on one a flat surface provided support rail (22) which is fixedly attached to the machine frame (104), is slidably mounted and is displaced by the associated driver (19) on the support rail (22), the endless conveyor consisting of a vertically arranged, inextensible, flexible Conveyor belt (17), in particular steel belt, which at the ends of a spinning group around deflection rollers (39, 40, 41, 42) is guided around with a vertical axis, and the drivers (19) on a machine-fixed guide rail (121) extending along the spinning station groups (12a, 12b) by means of complementary interlocking guide projections (93, 97) and guide recesses (94, 103) in the longitudinal direction are arranged displaceably guided, in particular according to one of the preceding claims,
characterized,
that the guide rail (121) is arranged below the support rail (22). Spinning machine, in particular a ring spinning machine with at least one group (12a, 12b) of spinning stations (11a to 11h; 11i to 11q) arranged at the same distance apart, a tube changing device (14) for the simultaneous exchange of full tubes (15) spooled with yarn for empty tubes (16 ) at each spinning station (11a to 11h; 11i to 11q) and one running along the spinning stations and from one end of the spinning station group (12a, 12b) or several spinning station groups to the other, the empty tubes (16) to the spinning stations (11 ) back and the full sleeves (15) away from the spinning stations (11) conveying synchronous endless conveyor (17) on which upright sleeve pins (13) are attached at a distance from the spinning stations (11) in such a way that each one with a sleeve changing position of the endless conveyor (17) Spinning station (11) is exactly aligned with a sleeve pin (13) individually assigned to it, with a spinning station group (1 2a) or a plurality of spinning unit groups, a full-sleeve unloading station (32), to which the endless conveyor (17) feeds the full sleeves (15) from the spinning unit group (12a, 12b) or the spinning unit groups successively and preferably an empty-tube loading station (33) is provided at the same end the the endless conveyor (17) feeds the empty tubes (16) successively to the spinning unit group (12a, 12b) or to the spinning unit groups, each sleeve journal (13) being arranged on its own journal carriage (18), the length of which in the conveying direction is slightly less than the distance between the two Adjacent spinning positions (11), each pin carriage (18) being assigned a carrier (19) that is structurally separate from it, but can be brought into detachable entraining engagement, which is attached to the endless conveyor (17) in such a position that when the driver (19) is in driving engagement with the assigned pin slide (18), the sleeve pin (13) of this pin slide (18) in the sleeve change position of the endless conveyor (17) is exactly aligned with the assigned spinning station (11), the pin slide (18 ) slidably mounted on a support rail (22) which is preferably provided with a flat surface and is fixedly attached to the machine frame (104) nd and moved by the associated driver (19) on the mounting rail (22), the endless conveyor consisting of a vertically arranged, inextensible, flexible conveyor belt (17), in particular steel belt, which at the ends of a spinning group around deflection rollers (39, 40 , 41, 42) is guided around with a vertical axis, and the drivers (19) on a machine-fixed guide rail (121) extending along the spinning unit groups (12a, 12b) by means of complementary interlocking guide projections (93, 97) and guide recesses (94 , 103) are arranged so as to be displaceable in the longitudinal direction, in particular according to one of the preceding claims,
characterized,
that the drivers (19) on the side facing the conveyor belt (17) have a contact surface (92) which extends over the entire width of the conveyor belt (17). Spinning machine, in particular a ring spinning machine with at least one group (12a, 12b) of spinning stations (11a to 11h; 11i to 11q) arranged at the same distance apart, a tube changing device (14) for the simultaneous exchange of full tubes (15) spooled with yarn for empty tubes (16 ) at each spinning station (11a to 11h; 11i to 11q) and one running along the spinning stations and from one end of the spinning station group (12a, 12b) or several spinning station groups to the other, the empty tubes (16) to the spinning stations (11 ) back and the full sleeves (15) away from the spinning stations (11) conveying synchronous endless conveyor (17) on which upright sleeve pins (13) are attached at a distance from the spinning stations (11) in such a way that each one with a sleeve changing position of the endless conveyor (17) Spinning station (11) is exactly aligned with a sleeve pin (13) individually assigned to it, with a spinning station group (1 2a) or a plurality of spinning unit groups, a full-sleeve unloading station (32), to which the endless conveyor (17) feeds the full sleeves (15) from the spinning unit group (12a, 12b) or the spinning unit groups successively and preferably an empty-tube loading station (33) is provided at the same end which the endless conveyor (17) feeds the empty tubes (16) successively to the spinning unit group (12a, 12b) or to the spinning unit groups, each sleeve journal (13) being arranged on its own journal carriage (18), the length of which in the conveying direction is slightly less than the distance two adjacent spinning positions (11), each pin carriage (18) being assigned a carrier (19) which is structurally separate from it but can be brought into engagement with it in a releasable manner and which is attached to the endless conveyor (17) in such a position, that when the driver (19) is in driving engagement with the assigned pin carriage (18), the sleeve pin (13) of this pin slide (18) is exactly aligned with the assigned spinning station (11) in the sleeve changing position of the endless conveyor (17), whereby the pin slides (18) on a preferably provided with a flat surface support rail (22) which is fixedly attached to the machine frame (104), are slidably mounted and are displaced by the associated driver (19) on the support rail (22), the Endless conveyor consists of a vertically arranged, inextensible, flexible conveyor belt (17), in particular steel belt, which is guided at the ends of a spinning group around deflecting rollers (39, 40, 41, 42) with a vertically standing axis, and the drivers (19) a machine-fixed guide rail (121) extending along the spinning station groups (12a, 12b) by means of complementary interlocking guide projections length (93, 97) and guide recesses (94, 103) guided in the longitudinal direction are arranged displaceably, in particular according to one of the preceding claims,
characterized,
that the guide rail (121) is arranged substantially at the same height as the conveyor belt (17). Spinning machine, in particular a ring spinning machine with at least one group (12a, 12b) of spinning stations (11a to 11h; 11i to 11q) arranged at the same distance apart, a tube changing device (14) for the simultaneous exchange of full tubes (15) spooled with yarn for empty tubes (16 ) at each spinning station (11a to 11h; 11i to 11q) and one running along the spinning stations and from one end of the spinning station group (12a, 12b) or more Spinning station groups, on the other hand, are traced back to themselves, the empty tubes (16) to the spinning stations (11) and the full sleeves (15) away from the spinning stations (11) conveying synchronous endless conveyors (17) on the upright at a distance from the spinning stations (11) Sleeve pins (13) are attached in such a way that when the endless conveyor (17) is in the case of a sleeve change, each spinning station (11) is exactly aligned with a sleeve pin (13) individually assigned to it, with a full sleeve unloading station () at one end of a spinning station group (12a) or several spinning station groups. 32), to which the endless conveyor (17) feeds the full sleeves (15) successively from the spinning group (12a, 12b) or the spinning group and preferably an empty tube loading station (33) is provided at the same end, from which the endless conveyor (17) supplies the empty tubes (16) successively feeds the spinning group (12a, 12b) or the spinning groups, each sleeve pin (13) on an egg nem is arranged its own trunnion carriage (18), the length of which in the conveying direction is slightly less than the distance between two adjacent spinning positions (11), with each trunnion carriage (18) being assigned a carrier (19) which is structurally separate from it but can be brought into releasable entraining engagement which is attached to the endless conveyor (17) in such a position that when a driver finger (19 ') on the driver (19) is in driving engagement with the associated journal carriage (18), the sleeve journal (13) of this journal carriage (18 ) in the sleeve change position of the endless conveyor (17) is exactly aligned with the assigned spinning station (11), the trunnion slide (18) sliding on a preferably provided with a flat surface support rail (22) which is fixedly attached to the machine frame (104) are stored and moved by the associated driver (19) on the mounting rail (22) The endless conveyor consists of a vertically arranged, inextensible, flexible conveyor belt (17), in particular steel belt, which is guided at the ends of a spinning group around deflecting rollers (39, 40, 41, 42) with a vertical axis, and wherein the drivers (19) on a machine-fixed guide rail (121) extending along the spinning unit groups (12a, 12b) are arranged so as to be displaceable in the longitudinal direction by means of complementary interlocking guide projections (93, 97) and guide recesses (94, 103), in particular according to one of the preceding claims ,
characterized,
that each driver (19) has, apart from the driver finger (19 '), a preferably resilient holding arm (90, 91) which engages from the opposite side on the pin carriage (18) and which together with the driver finger (19') also has the pin carriage (18) leads in the direction transverse to the conveying direction. Spinning machine according to one of the preceding claims, characterized in that the support rail (22) forming a flat sliding surface preferably slopes somewhat obliquely at an angle of 5 to 15 °, in particular 10 ° to the front. Spinning machine according to one of the preceding claims, characterized in that the guide rail (121) combined with the support rail (22) can be inserted into the machine frame (104) as a uniform component (22, 121). Spinning machine according to claim 13, characterized in that the guide rail (121) in its lower region bearing surfaces (107, 108), a rear, under a Guide rail (105) of the machine frame (104) engaging retaining projection (106) and an upper clamping surface (109) on which a removable machine-fixed clamping bar (110) engages. Spinning machine according to claim 12, characterized in that the driver finger (19 ') runs parallel to the support rail (22) over part of its length, and in that the end of the driver finger (19') lies horizontally, so that the driver finger (19 ') as a whole is angled.

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