The present application claims priority from German Utility Model Application No. 20 2007 010 686.6 dated Jun. 29, 2007, German Patent Application No. 10 2007 038 667.4 dated Aug. 15, 2007, and German Patent Application No. 10 2008 004 095.9 dated Jan. 11, 2008, the entire disclosure of each of which is incorporated herein by reference.
The invention relates to an apparatus for the fibre-sorting or fibre-selection of a fibre bundle comprising textile fibres, especially for combing.
In a known apparatus, fibre material is supplied by means of a supply device to a fibre-sorting device, especially to a combing device, in which clamping devices are provided, which clamp the fibre bundle at a distance from its free end and mechanical means are present which generate a combing action from the clamping site to the free end of the fibre bundle in order to loosen and remove non-clamped constituents, such as, for example, short fibres, neps, dust and the like from the free end.
In practice, combing machines are used to free cotton fibres or woollen fibres of natural impurities contained therein and to parallelise the fibres of the fibre sliver. For that purpose, a previously prepared fibre bundle is clamped between the jaws of the nipper arrangement so that a certain sub-length of the fibres, known as the “fibre tuft”, projects at the front of the jaws. By means of the combing segments of the rotating combing roller, which segments are filled with needle clothing or toothed clothing, this fibre tuft is combed and thus cleaned. The take-off device usually consists of two counter-rotating rollers, which grip the combed fibre bundle and carry it onwards. The known cotton-combing process is a discontinuous process. During a nipping operation, all assemblies and their drive means and gears are accelerated, decelerated and in some cases reversed again. High nip rates result in high acceleration. Particularly as a result of the kinematics of the nippers, the gear for the nipper movement and the gear for the pilgrim-step movement of the detaching rollers, high acceleration forces come into effect. The forces and stresses that arise increase as the nip rates increase. The known flat combing machine has reached a performance limit with its nip rates, which prevents productivity from being increased. Furthermore, the discontinuous mode of operation causes vibration in the entire machine, which generates dynamic alternating stresses.
EP 1 586 682 A discloses a combing machine in which, for example, eight combing heads operate simultaneously one next to the other. The drive of those combing heads is effected by means of a lateral drive means arranged next to the combing heads having a gear unit, which is in driving connection by way of longitudinal shafts with the individual elements of the combing heads. The fibre slivers formed at the individual combing heads are transferred, one next to the other on a conveyor table, to a subsequent drafting system in which they are drafted and then combined to form a common combing machine sliver. The fibre sliver produced in the drafting system is then deposited in a can by means of a funnel wheel (coiler plate). The plurality of combing heads of the combing machine each have a feed device, a pivotally mounted, fixed-position nipper assembly, a rotatably mounted circular comb having a comb segment for combing out the fibre tuft supplied by the nipper assembly, a top comb and a fixed-position detaching device for detaching the combed-out fibre tuft from the nipper assembly. The nipper assembly comprises a lower nipper, which co-operates with an upper nipper plate. The upper nipper plate is here pivotally mounted on the lower nipper by way of a pivot axis. The lower nipper and the upper nipper are formed with complementary profiles at their front end region, via which, when the nipper assembly is closed, they clamp the lap supplied via a feed cylinder. The fibre tuft FB protruding in this clamped position from the nipper assembly is combed by a comb segment of a circular comb. The circular comb arranged beneath the nipper assembly is secured, without relative rotation, on a circular comb shaft, which is connected via the drive connection to the gear mechanism. The drive of the gear mechanism is effected by a main motor. The nipper assembly is pivotally mounted on the axis of the circular comb shaft via a pivot arm. The free end of the pivot arm is fixedly secured to the frame of the lower nipper. In its rear region, the lower nipper has a pivot axis, on which a lever is rotatably mounted. This lever is rotatably secured via an axle to a crank disc. The axle of the crank disc is in connection via a drive connection with a drive motor. The motor is in connection with the central control unit via the control line. In order to co-ordinate the electromotive drives with the drive of the circular comb, a sensor is provided, which is in connection with the control unit via the line. The function of this sensor is to detect the particular angular position of the shaft of the circular comb and relay this to the control unit. It is thus possible to output appropriate control pulses to the relevant motors via the control unit, so that, on the one hand, the combing segment combs out the fibre tuft FB at a defined point in time and, on the other hand, the rotary movement of the detaching roller pair respectively the transport roller pair is co-ordinated with the nipper movement. In this way, a mechanical combing of the fibre material is effected. Disadvantages of that combing machine are especially the large amount of equipment required and the low hourly production rate. There are eight individual combing heads which have in total eight feed devices, eight fixed-position nipper assemblies, eight circular combs with comb segments, eight top combs and eight detaching devices. A particular problem is the discontinuous mode of operation of the combing heads. Additional disadvantages result from large mass accelerations and reversing movements, with the result that high operating speeds are not possible. Finally, the considerable amount of machine vibration results in irregularities in the deposition of the combed sliver. Moreover, the ecartement, that is to say the distance between the nipper lip of the lower nipper plate and the clamping point of the detaching cylinder, is structurally and spatially limited. The rotational speed of the circular comb is co-ordinated with the slow (discontinuous) combing process, in particular the discontinuous and slow movements of the nippers, and is limited by this. In addition, the profiled end regions of the upper and lower nipper suffice for the feed respectively positioning at slow speed of the fibre tuft to be combed out. High-speed combing with this apparatus is not possible.
It is an aim of the invention to provide an apparatus of the kind described at the beginning which avoids or mitigates the mentioned disadvantages and which in a simple way, in particular, enables the amount produced per hour (productivity) to be substantially increased and an improved combed sliver to be obtained.
The invention provides an apparatus for the fibre-sorting or fibre-selection of a fibre bundle comprising textile fibres having:
By implementing the functions of clamping and moving the fibre bundles to be combed-out on rotating rollers, high operating speeds (nip rates) are achieved—unlike the known apparatus—without large mass accelerations and reversing movements. In particular, the mode of operation is continuous. When high-speed rollers are used, a very substantial increase in hourly production rate (productivity) is achieved which had previously not been considered possible in technical circles. A further advantage is that the rotary rotational movement of the roller with the plurality of clamping devices leads to an unusually rapid supply of a plurality of fibre bundles per unit of time to the first roller and to the second roller. In particular the high rotational speed of the rollers allows production to be substantially increased.
To form the fibre bundle, the fibre sliver pushed forward by the feed roller is clamped at one end by a clamping device and detached by the rotary movement of the turning rotor. The clamped end contains short fibres, the free region comprises the long fibres. The long fibres are pulled by separation force out of the fibre material clamped in the feed nip, short fibres remaining behind through the retaining force in the feed nip. Subsequently, as the fibre bundle is transferred from the turning rotor onto the combing rotor the ends of the fibre bundle are reversed: the clamping device on the combing rotor grips and clamps the end with the long fibres, so that the region with the short fibres projects from the clamping device and lies exposed and can thereby be combed out.
The fibre bundles are—unlike the known apparatus—held by a plurality of clamping devices and transported under rotation. Because a plurality of clamping devices is available for the fibre bundles, in an especially advantageous manner fibre bundles can be supplied to the first and second roller respectively one after the other and in quick succession, without undesirable time delays resulting from just a single supply device for each clamping device. Advantageously, the fibre bundles supplied to the rollers are additionally acted upon by suction for support. Here, the free end of the fibre bundles is gripped very quickly and drawn into the clamping device whilst the clamping device is open, which leads to a further considerable increase in production speed. The suction air currents advantageously have an influence on the alignment and movement of the fibre bundles to be transported. A particular advantage is that, owing to the high-speed rollers, a plurality of fibre slivers can be combed out by the combing elements in a very short time. For that purpose, means, for example, pneumatic and/or mechanical means, are associated with the combing elements for optimum feed and/or positioning of the fibre material to be combed. Through the rotary arrangement of the clamping devices on a high-speed roller that rotates without interruption, it is possible to supply a plurality of fibre bundles in a short time to just a few combing elements. A considerable structural simplification is thereby implemented.
Advantageously, a guide device is present for feed and/or positioning. The guide device may be, in certain embodiments, a pneumatic guide device. For example, the guide means comprise a suction device, or the guide means comprise a blowing device. In other embodiments, a mechanical guide device may be present.
Advantageously, there are fewer combing elements than clamping elements which co-operate with the combing elements. In some embodiments the device for combing is associated with the periphery of the combing rotor. In other embodiments, the device for combing is arranged at and opposite the periphery of the combing rotor. In yet further embodiments, the device for combing is arranged opposite and spaced from the periphery of the combing rotor. In certain embodiments, additional elements, e.g. for optimum fibre bundle feed, are integrated in the combing rotor.
Advantageously, the distance of the device for combing from the combing rotor is adjustable. Advantageously, a fibre bundle separated from the fibre lap is fed to the device for combing. Advantageously, on feed to the device for combing the fibre bundle is stationary in relation to the clamping site on the combing rotor. Advantageously, the clamped fibre bundle moves in rotation around the rotor axis in the direction of flow of the material. Advantageously, a plurality of devices for combing are arranged in succession in the direction of flow of the material. Advantageously, a plurality of devices for combing the fibre bundle are present, the spacing of the combing elements in the direction of flow of the material being variable. Preferably, the spacing of the combing elements in the direction of flow of the material becomes continuously smaller. In some embodiments, the combing elements are circular combs. In other embodiments, the combing elements are rollers. In yet further embodiments, the combing elements are endlessly revolving combing elements (revolving card flats). Advantageously, the device for combing is rotatably mounted axially parallel with respect to the combing rotor. Advantageously, with respect to the circulation as a whole, the circulating combing elements are positionable with a constant spacing from the combing rotor. In some embodiments, the circulating combing elements are positionable in the direction of flow of the material-with respect to the circulation as a whole in a wedge shape, e.g. with an increasingly smaller spacing from the combing rotor. For example, the individual elements (combing elements) may have a positive offset or, instead, the individual elements (combing elements) may have a negative offset.
In some embodiments, the narrow point in respect of the combing rotor is positionable in the middle of the individual element (combing element). In certain embodiments, the individual elements (combing elements) are of straight construction. In other embodiments, the individual elements (combing elements) have a curved geometry corresponding to the diameter of the combing rotor, so that a constant combing nip is ensured over the circulation as a whole. In some embodiments, the direction of rotation of the combing elements is effected in the same direction as the combing rotor. In other embodiments, the direction of rotation of the combing elements is effected opposite to the direction of the combing rotor. Advantageously, the speed of circulation of the combing elements is adjustable. Advantageously, the productivity of the rotor combing machine is independent of the relative speed between combing element and fibre bundle.
Where the directions of rotation of the combing elements and the combing rotor are the same the speed ratio between the speed of the combing rotor and the speed of the combing element is advantageously greater than 1. Where the directions of rotation of the combing elements and the combing rotor are opposite, the speed ratio between combing rotor and combing elements is advantageously greater than 1. It may be preferred, however, that with opposite directions of rotation the speed ratio between combing rotor and combing elements is less than 1, or is equal to 1.
Where a plurality of devices is used for combing the fibre bundle, to achieve an optimum combing result the directions of rotation of the combing elements and the speed ratios can advantageously be selected to be different. Advantageously, as final combing-out step, the combing element is operable in counter direction, in order to re-comb the already pre-cleaned fibre bundle intensively.
Advantageously, when using e.g. a circular comb as combing element, a stripper element, a cover element, a holding-down element or the like can be used, wherein the useful combing length is adjustable in a defined manner. Preferably the stripper element, the cover element, the holding-down member or the like are exchangeable and adjustable in their position with respect to the combing element.
Advantageously, the surface of the combing element comprises an all-steel clothing. In some embodiments, the surface of the combing element comprises flexible clothings. In other embodiments, the surface of the combing element comprises needles. Advantageously, when configuring the surface, fully clothed surfaces can be used, e.g. clothed circular comb rollers. Advantageously, clothed segments that cover the entire surface can be used on the surface of the combing element. If desired, clothed segments that cover only a part of the surface can be used on the surface. In certain embodiments, the segments may be mounted on the surface in a wedge form. In other embodiments, clothings having a continuously increasing height can be used. Advantageously, when using a plurality of devices for combing the fibre bundle, surfaces on the combing elements that are different in respect of the tip density can be used. Advantageously, when using a plurality of devices for combing the fibre bundle, surfaces on the combing elements that are different in respect of the working angle can be used. Advantageously, when using a plurality of devices for combing the fibre bundle, surfaces on the combing elements that are different in respect of clothing height can be used.
In some embodiments, for optimum feed of the fibre bundle to the combing element, an air jetting (compressed air jet or compressed air jets) from the combing rotor is effected. Advantageously, the air jetting pressure is adjustable. Advantageously, the air jetting angle is adjustable. Advantageously, the position of the nozzles is adjustable.
In other embodiments, for optimum feed of the fibre bundle to the combing element, an externally mounted nozzle arrangement is present.
Advantageously, the air jetting pressure/or the air jetting angle and/or the position of the nozzles of the externally mounted nozzle arrangement are adjustable.
In further embodiments, an optimum feed of the fibre bundle to the combing element is effected by the nipper geometry of the combing rotor nippers, wherein a mechanical guidance is present.
In yet further embodiments, an optimum feed of the fibre bundle to the combing element is effected by guide elements at the periphery of the combing rotor, wherein a mechanical guidance is implemented.
Advantageously, the spacing and/or the position of the guide elements with respect to the combing rotor is adjustable. In some embodiments, guide elements retractable into the combing rotor (retraction during the combing process) are present.
Advantageously, for optimum feed of the fibre bundle to the combing element, the combing element (e.g. cylindrical surface) and/or clothing has air outlet openings and is connected to a source of reduced pressure. In some embodiments, the cylindrical surface of the combing element may have air passage openings. In other embodiments, the clothing that is positioned on the cylindrical surface of the combing element, comprises e.g. a profiled clothed foot, which is air permeable. In yet further embodiments, the clothed segments comprise a profiled foot, in order to be air permeable. When using clothed segments the air passage openings may be located, for example, between the individual segments. When using flexible clothings the card top material, that is the base, may be perforated. Advantageously, the reduced pressure is adjustable. The combing element may be continuously acted upon by suction or may instead be acted upon by suction on a timed basis.
Advantageously, a portion of the inner cylindrical surface of the take-off roller is sealable by a screen element. Advantageously, the spacing of the screen elements from the combing element in the radial direction is small. The spacing of the screen elements from the combing element may amount to, for example, 0 mm, e.g. when using slide seal rings.
Advantageously, a cleaning device is associated with the combing element. Advantageously, the cleaning device is a rotating roller. Preferably, the roller has wires, bristles or the like on its periphery. Preferably, the cleaning device includes an extraction device. Preferably, the cleaning device includes a stripper, scraper or the like.
In some embodiments, the cleaning is designed analogously to the cleaning of the card top circulation of a card. In other embodiments, the cleaning is designed analogously to the cleaning of a circular comb. In yet further embodiments, the cleaning is designed analogously to the cleaning of a stripping roller. Preferably, a cleaning device is capable of cleaning at least two combing elements.
In certain preferred embodiments, the at least two rotatably mounted rollers that run rapidly without interruption comprise a turning rotor and a combing rotor. Preferably, the turning rotor and the combing rotor have opposite directions of rotation. Advantageously, for the suction of the supplied bundles, at least one suction device is associated with the clamping devices in the region of the take-up of the fibre bundle from the supply device to the to the first roller and/or in the region of the transfer of the fibre material from the first roller to the second roller.
The invention also provides an apparatus for the fibre-sorting or fibre-selection of a fibre bundle comprising textile fibres, especially for combing, which is supplied by means of a supply device to a fibre-sorting device, especially a combing device, in which clamping devices are provided which clamp the fibre bundle at a distance from its free end, and mechanical means are present which generate a combing action from the clamping site to the free end of the fibre bundle, in order to loosen and remove non-clamped constituents, such as, for example, short fibres, neps, dust and the like from the free end, characterised in that that downstream of the supply device there are arranged at least two rotatably mounted rollers rotating rapidly without interruption which is provided with clamping devices for the fibre bundle transported in rotation, which clamping devices are distributed spaced apart in the region of the periphery of at least one of said rollers, and the means for generating a combing action (combing elements) are associated with a said roller, wherein means for optimum feed and/or positioning of the fibre material to be combed are associated with the means for generating a combing action.
a to 8c show a holding-down element (
a and 9b show individual combing elements of straight (
a shows a clothing with continuously increasing height in the combing segment,
b shows the dependence of the combing nip on the combing length,
c shows a clothing mounted in a wedge-shaped intermediate element,
a to 11c show the influence of the nipper geometry on the fibre bundle feed,
a, 13b show a slidable (13a) and pivotable (13b) guide element at the periphery of the combing rotor for optimal feed of the fibre bundle,
a shows to an enlarged scale a cut-out from
With reference to
An autoleveller drafting system 50 (see
In accordance with a further construction, more than one rotor combing machine 2 is provided. If, for example, two rotor combing machines 2a and 2b are present, then the two delivered comber slivers 17 can pass together through the downstream autoleveller drafting system 50 and be deposited as a drafted comber sliver in the sliver-deposition device 3.
The sliver-deposition device 3 comprises a rotating coiler head 3a, by which the comber sliver can be deposited in a can 3b or (not shown) in the form of a can-less fibre sliver package.
The first roller 12 is provided in the region of its outer periphery with a plurality of first clamping devices 18 which extend across the width of the roller 12 (see
The second roller 13 is provided in the region of its outer periphery with a plurality of two-part clamping devices 21, which extend across the width of the roller 13 (see
In an embodiment shown in
In the embodiment of
The first roller 12 is provided in the region of its outer periphery with a plurality of first clamping devices 18 which extend across the width of the roller 12 (see
The second roller 13 is provided in the region of its outer periphery with a plurality of two-part clamping devices 21, which extend across the width of the roller 13 (see
In the embodiment of
a to 8c show arrangements suitable for adjusting the combing length in embodiments in which a circular comb is used as a combing element. When using a circular comb 34, lying opposite its surface is, according to
The combing teeth 33 of the combing element 31 can be aligned straight (
When using combing segments 31, these can be mounted, as shown in
a to 11c illustrated the influence of the nipper geometry on the feed of the fibre bundle. The upper nipper 22 and the lower nipper 23 have in their front end region profiles of complementary construction, by means of which, with the nipper assembly closed, they clamp an end region of the fibre tuft 303. The fibre bundle protruding in this clamped position from the nipper assembly is combed by a combing segment 31, e.g. of a circular comb 34. In this way, an optimum feed of the free end of the fibre bundle 303 to the combing element 31 is effected by virtue of the nipper geometry of the combing rotor nippers 21 (comprising upper nipper 22 and lower nipper 23) and hence by mechanical guidance.
Optimum feed of the free end of the fibre bundle 303 can in other embodiments be effected by a slidable guide element 45 (
In the embodiment of
When using combing segments 31, these can be mounted, as shown in
Additionally, a blowing flow can be provided in the region of the supply device 8 and/or in the region of transfer between the rollers. The source of the blowing flow (blowing nozzle 39) is arranged inside the feed roller 10 and has effect, through the air-permeable surface of the supply device or air passage openings, towards the outside in the direction of the first roller. Also, in the region of the supply device 8, the element for producing the blown air current can be fixedly arranged, directly under or over the supply device 8. In the region of the transfer between the rollers 12, 13 the blown air current sources can be arranged at the perimeter of the first roller 12, directly under or over each nipper device. For the blown air generation there may be used compressed air nozzles or air blades.
In the embodiment of
As a result of the provision of additional air guide elements 60 and lateral screens 61, 62 the direction of the flow can be influenced and the air carried round with the rotors separated off. In that way the time for alignment can be further shortened. In particular, a screen element between the first rotor 12 and supply device 8 over the lap and a screen element on each side of the roller have proved useful.
In the interior of the rotor 13 there is an increased pressure region 67, which generates a pressure flow U at a pressure opening 68. The increased pressure can be generated by connecting to a flow-generating machine. The pressure flow at the pressure opening 68 can be so switched between increased pressure region and pressure opening 68 that it is applied only at particular selected angular positions on the roller periphery. For the purpose of the switching, valves or the valve pipe 58 with the pressure opening 68 in the corresponding angular positions can be used. The pressure opening 68 is connected to an air passage opening 71. Furthermore, it is possible to arrange a region of increased pressure only at the corresponding angular positions. In the region between the valve pipe 58 and the outer periphery of the roller 13, associated with each nipper pair 21 is a pressure line 69, which passes through the lower nipper 23 and the upper nipper 22 (see
Using the rotor combing machine 2 according to the invention, more than 2000 nips/min, for example from 3000 to 5000 nips/min, are achieved.
In use of the rotor combing machine according to the invention there is achieved a mechanical combing of the fibre material to be combed out, that is, mechanical means are used for the combing. There is no pneumatic combing of the fibre material to be combed, that is, no air currents, e.g. suction and/or blown air currents, are used for combing.
In the rotor combing machine according to the invention there are present rollers that rotate rapidly without interruption (continuously) and that have clamping devices. Rollers that rotate with interruptions, stepwise or alternating between a stationary and rotating state are not used.
In the interior of the rotor 13 there is an increased pressure P+ region 67, which generates a pressure flow U at a pressure opening 68. The increased pressure can be generated by connecting to a flow-generating machine. The pressure flow at the pressure opening 68 can be so switched between increased pressure region and pressure opening 68 that it is applied only at particular selected angular positions on the roller periphery. For the purpose of the switching, valves or the valve pipe 58 with the pressure opening 68 in the corresponding angular positions can be used. The pressure opening 68 is connected to an air passage opening 71. Furthermore, it is possible to arrange a region of increased pressure only at the corresponding angular positions. In the region between the valve pipe 58 and the outer periphery of the roller 13, associated with each nipper pair 21 is a pressure line 69, which passes through the lower nipper 23 and the upper nipper 22 (see
Although the foregoing invention has been described in detail by way of illustration and example for purposes of understanding, it will be obvious that changes and modifications may be practised within the scope of the appended claims.
Number | Date | Country | Kind |
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10 2007 030 471 | Jun 2007 | DE | national |
20 2007 010 686 U | Jun 2007 | DE | national |
10 2007 038 667 | Aug 2007 | DE | national |
10 2008 004 095 | Jan 2008 | DE | national |
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