EP2503035A1 - Stretcher with compaction device on a spinning frame - Google Patents

Abstract

The drafting device (1) has a preliminary traverse device, through which a fiber material (F) is fed into the drafting device with laterally extending traversing movement of the fiber material into a conveying direction. A clamping point (D) is formed with a compression unit. A rotation locking roller comprises a cylindrical body forming a clamping portion in the direction of a rotational axis (14) of the rotation locking roller.

Description

The invention relates to a drafting of a spinning machine with an upstream traversing device over which the fiber material is fed to the drafting with a laterally to the conveying direction of the fiber material traversing movement and with a subsequent compression device, which has a circumferential, pressurized with negative compression means, with a Suction zone is provided, to which the pulp discharged from drafting material is attracted under the action of a suction air flow, wherein the suction zone is provided with distributed over the circumference of the compression means perforations and following the suction zone, a rotation locking roller is provided with the compression means a nip forms, from which the fiber is fed to a subsequent swirl-forming device.

From the DE 44 48 021 is a drafting device of a spinning machine, which is provided with a compacting device. In this case, the lower roller of the output roller pair of the drafting system is designed as a suction drum (compression means), on which a pressure roller and a subsequent rotation locking roller rests and each form a nip with this. Between the pressure roller and the rotation locking roller is the compression area for the stretched fiber material. Above the compression area a shield in the form of a Umlenkschirmes is provided. Under the influence of a negative pressure applied to the suction drum, the drawn-out fiber material discharged from the drafting system is sucked into the center region of the suction drum, in which the suction drum is provided with circumferential perforations. In this case, the fiber material is compacted, wherein the outwardly projecting fibers are involved under the action of the suction air stream. Before entering the drafting device, the fiber material is passed through a traversing device, via which it is alternated transversely to its conveying direction during the passage through the drafting device. With the traversing of the wear of the provided with a coating pressure rollers of the drafting system is reduced.

As a result of the traversing movement, the delivery point of the stretched fiber material continuously changes in time sequence to the surface of the compacting device. In this case, the traversing movement - viewed transversely to the conveying direction of the fiber material - extends on both sides of the

Compression range. Subsequent to the nip of the rotation locking roller, a spinning triangle forms under the influence of a subsequent swirl-forming device.

From the published pamphlets DE-102 27 463 C1 . EP-0 924 323 A2 and EP-0 947 614 A2 Embodiments are known, wherein compression devices, which also have a rotation locking roller, are arranged directly after the drafting device. The inventive embodiment also relates to such versions.

If the suction effect on the compacting device fails or is reduced, the compaction effect correspondingly deteriorates or disappears altogether, as a result of which the hairiness of the yarn increases. It may now happen that it is inside the compaction device, for. Inside a suction insert of the compacting device (eg, a suction drum), clogging occurs due to an accumulation of sucked fiber fly and other debris. This clogging leads to a reduction or to a lack of suction power at the compression surface and thus to a deterioration of the yarn quality. Devices have therefore been proposed to monitor the drop in suction power and to trigger appropriate measures to shut down the corresponding spinning station.

Such a device is z. B. from the EP-1 352 999 A2 can be seen, with a separate, hinged flap is attached to monitor the Saugluftströmung. In this case, this flap, which faces a circumferential and perforated straps, changes its position as soon as a disturbance of Saugluftströmung occurs. This position change can be detected by correspondingly attached buttons or visually. With such a flap, it is possible to carry out a targeted monitoring of Saugluftströmung. The attachment of such a flap requires additional space, which is usually not available in the region of the compression device, in particular, if the Compression is covered by an air guide. In addition, additional moving parts are needed, which are also susceptible to contamination.

It is now the object of the invention to avoid the disadvantages of the known solutions and to propose a device in which without the use of additional monitoring means the further yarn formation is automatically interrupted in the event of waste or failure of the suction on a compacting device or a compacting means.

It is advantageous if, during the compression process with an intact compression device, no air flows are produced which can negatively influence the compression. D. h., On the, guided through the compression region through fiber material to act essentially air flows, which are aligned transversely to the conveying direction.

This object is achieved by proposing that - seen in the direction of the axis of rotation of the rotation locking roller - the rotation locking roller has a cylindrical, the nip forming portion to which each connect to the ends of the rotation locking roller projecting portions which are stepped or continuous in reduce their diameter toward the ends, wherein the width of the cylindrical portion of the rotation locking roller is greater than the width of the suction zone and - seen in the conveying direction of the fiber material - at least one of the reversal points of the traverse path outside the cylindrical portion of the rotation locking roller and within a cylindrical portion subsequent section lies.

The "rotation barrier roll" is a "roll" in which a "spinning triangle" is formed at the exit under the action of a subsequent swirl-forming device. This device can, for. Example, consist of a ring / runner combination, wherein the now provided with a spin fiber material (yarn) is wound onto a spindle to form a cop. The twisted fiber material (yarn), which is formed following the rotation locking roller, has a substantially higher adhesive force than the fiber material, which is in the region of the compression zone between the nip of the pair of output roller Drafting and the clamping point of the rotation locking roller is located. This circumstance makes use of the invention. D. h., Which is a clamping point for the fiber material forming central cylindrical portion of the rotation locking roller in accordance with the traversing movement of the fiber material so dimensioned in its width, so that during sections of traversing movement, the discharge direction of the fiber material from the pair of rollers of the drafting outside the middle cylindrical part of the rotation locking roller extends. Ie. at least one of the reversal points of the traversing movement is - viewed in the conveying direction of the fiber material - outside the width of the central cylindrical portion of the rotation locking roller and within an adjoining the cylindrical portion sections.

During undisturbed operation, the fiber material discharged from the pair of delivery rollers of the drafting system is moved toward the suction zone under the action of the applied suction flow and compacted there. Only when overlap by the traversing movement of the delivery point of the fiber material in the pair of output rollers of the drafting and the suction zone, no lateral displacement of the fiber material by the suction air flow instead. By the laterally adjoining the middle cylindrical part of the rotation-locking roller, stepwise or continuously decreasing in diameter sections, on the one hand ensures that in this area no nip is formed with the compression means and on the other hand, the suction region remains substantially sealed off by these sections. This ensures that no air flow is created by the suction effect, which is opposite to the conveying direction of the fiber material.

The width of the suction zone is defined by the perforations disposed on the circumference of the compacting means communicating with a suction slot of corresponding width of a suction insert disposed within the compacting means. As a rule, the width of the suction slot corresponds to the width of the suction zone. The suction slot is disposed in the region between the pair of output rollers of the drafting system and the nip of the rotation locking roller and may include various cross sections and configurations. Is located in a failure of the suction, the delivery point of the fiber material from the output rollers of the drafting - seen in the conveying direction - outside the Area of the central cylindrical portion of the rotation locking roller, this fiber material is no longer displaced laterally and enters the region of the adjoining the cylindrical portion, tapered portions which do not form a nip with the compression means. Thus, the tensile force, which is applied to the, provided with a twist yarn, also acts on the unrotated portion of the fiber material in the region between the terminal point of the output roller pair of the drafting system and the rotation locking roller. However, this untwisted portion of the fiber material has a substantially lower adhesive force than the twisted yarn, so that it comes through the action of the tensile force described to a demolition of the fiber material in this section. The torn-off end projecting from the drafting system is then caught and sucked off by a suction device attached to each drafting system. Thus, the production of non or partially compressed yarn is interrupted at this spinning station. The missing yarn feed to the take-up device can be detected by a sensor and communicated visually or via an electrical signal to the operator.

It is proposed that the width of the cylindrical portion of the rotation locking roller is smaller than the path of traversing movement. This makes it possible to lay the traversing region with respect to the central cylindrical portion of the rotation locking roller so that - seen in the conveying direction of the fiber material - the reversal points of the traversing movement are on both sides outside the cylindrical central portion.

Furthermore, it is proposed that the cylindrical section is between 6 and 10 mm. It must be smaller than the traverse path, provided that the traversing movement extends over both ends of the cylindrical portion. Advantageously, the adjoining on both sides of the cylindrical portion of the rotation locking roller portions may be formed conically, each tapering towards the ends of the rotation locking roller. Thus, the foreclosure of the compression area relative to the area in connection to the rotation locking roller can be substantially maintained, whereby undesirable air flows in the compression area can be avoided.

The taper angle of the cones can be between 1 ° and 20 °.

It is also conceivable embodiment, wherein the central cylindrical portion of the rotation locking roller on both sides of at least one cylindrical section with a smaller diameter than the middle section adjoins. The outer sections adjoining the central section can also consist of a plurality of cylindrical sections which are step-shaped towards the respective ends and reduce in diameter.

Further advantages of the invention will be shown and described in the following exemplary embodiments.

Fig.1

eine schematische Seitenansicht einer Streckwerksvorrichtung einer Ringspinnmaschine mit einer Verdichtungsvorrichtung.

Fig.1a

ein weiteres Ausführungsbeispiel einer Streckwerksvorrichtung mit einer Verdichtungsvorrichtung nach Fig.1

Fig.2

eine Ansicht X nach Fig.1

Fig.3

ein Ausführungsbeispiel nach Fig.2 mit einer erfindungsgemäss ausgebildeten Drehungssperrwalze

Fig.4

ein weiteres Ausführungsbeispiel der Drehungssperrwalze nach Fig.3

Fig.4a

eine weitere Ausführungsform der Drehungssperrwalze nach Fig. 4

Show it:

Fig.1

a schematic side view of a drafting device of a ring spinning machine with a compacting device.

1a

a further embodiment of a drafting device with a compression device according to Fig.1

Fig.2

a view X after Fig.1

Figure 3

an embodiment after Fig.2 with an inventively designed rotation locking roller

Figure 4

Another embodiment of the rotation locking roller after Figure 3

4a

a further embodiment of the rotation locking roller after Fig. 4

Fig. 1 shows a drafting device 1 (of a plurality of juxtaposed Drafts arrangements) of a spinning machine (ring spinning machine), not shown, wherein the drafting device (in short "drafting" called) in the present example consists of three pairs of rollers. These are formed from an input roller pair 2, 3 to which a middle roller pair 5, 6 is arranged downstream. The fiber roving F (roving) drawn off from a roving bobbin S is fed via a deflection 10 and a subsequent traversing device 20 to the drafting system 1 via the nip Z of the inlet rollers 2, 3. As in particular from the top view X from Fig.2 can be seen, the traversing device 20 performs a lateral traversing movement with a traversing c within the reversal points U1, U2, which is directed transversely to the conveying direction FS. The traversing device is not one connected drive connected. By traversing the life of the drafting rollers, in particular the pressure rollers is increased, which are provided with a rubber coating.

The speed of the center rollers 5, 6 is slightly increased relative to the speed of the input rollers 2, 3, whereby a pre-distortion of the roving F takes place between these pairs of rollers. To the center rollers 5, 6, a respective straps 11, 12 are guided, which are each held around a cage not shown in detail in its illustrated position. After leaving the nip line Z1 between the center rolls 5, 6, the roving F drawn with a preliminary draft is transferred with the aid of the aprons 11, 12 to the clamping point Z2 of a pair of delivery rollers 8, 9. The output rollers 8, 9 have a much higher speed than the center rollers 5, 6, wherein between the clamping points Z1 and Z2 a main delay of the roving F takes place. In general, the rollers 3, 6, 9 are directly connected to a drive not shown in detail, while the rollers 2, 5 and 8 rest under a compressive load on the rollers 3, 6 and 9 and are driven by this via friction.

The output roller 9 is carried out in the present example as a driven suction roll, which is provided in its central region with extending over the entire circumference perforations or openings O, in particular from the view X in Fig. 2 can be seen. As shown schematically, a stationary attached suction unit 50 is mounted within the suction roll 9. The suction unit 50 has, on the side which faces the inner surface IF of the suction roll 9, a schematically indicated suction opening 51 (eg a suction slot) which runs along a compression area V and is connected to a vacuum source via lines not shown. Above the compression region V is at a distance from the peripheral surface AF, an air guide element 16 is mounted to ensure a lateral air supply, which is necessary for an optimal compression process. This is shown schematically in Fig.2 shown by arrows. More information on the compression process and the necessary air flow are published DE-44 48 021 B4 refer to.

By the following after the suction zone SZ, or the compression region (also called "fiber compression") arranged and with the suction roll 9 a nip line D forming rotational locking roller 14, the stretched and compacted fiber material of a subsequent swirl-forming device 40 is supplied.

By the rotation locking roller 14 is a foreclosure of the compression region V of the suction zone SZ relative to the surrounding area, which follows the rotation locking roller. This avoids that air is sucked in directly via the suction slot 51 from the described surrounding area, which would bring about an air flow counter to the conveying direction FK of the fiber material. However, such an opposing vent flow would adversely affect the compression process. As a result, care must be taken when changing or adapting the rotation locking roller that, as in the case of the known solutions, there is no counterflowing air flow.

In the schematic partial view Fig. 1a a further embodiment of a route 1 with a compression device is shown, in which also according to the invention claimed embodiment of a rotation locking roller 14a, 14b may be used, as in the Fig.3 and Fig.4 will be described and shown below. In this case, the suction roller 9 is arranged with a suction insert 50 following an output roller pair 9a, 8 of the track 1. The drive of the suction roller 9 can be removed from the output lower roller 9a. The rotation lock roller rests with a pressure force on the suction roller 9 and forms a nip D.

Likewise, the inventive design of a rotation locking roller 14a, 14b applicable if instead of the suction roller 9 shown, a not-shown circumferential straps is used, such. B. in the DE 10 2006 033 388 A1 has been shown.

As from the double arrow in Fig.2 2, the fiber material F supplied via the traversing device 20 to the nip line Z is displaced transversely to the conveying direction FS during operation in a specific time interval (eg 1 to 5 minutes) between the reversal points U1, U2. Here are - viewed transversely to the conveying direction - the traversing c and the suction zone SZ with the width s centered to each other. Is the feed of the fiber F F z. B. in the area of one of Reversal points U1 or U2, it is guided in this position by the drafting system 1 to the nip Z2, as can be seen from the dashed lines shown.

After passing through the nip Z2 of the pair of output rollers 8, 9, the fiber material F enters the effective range of the suction air flow, which is generated via the suction slot 51 in the region of the suction zone SZ, as indicated by arrows. Under the influence of the suction air flow between the peripheral surface AF and the air guiding element 16, the fiber material emerging from the clamping line Z2 is deflected in the direction of the suction slot 51 or to the suction zone SZ.

Subsequently, the fiber material is guided on the perforated outer surface AF above the suction slot 51 in the suction zone SZ to the clamping point D of the rotation locking roller 14 and simultaneously compressed. From the clamping point D, the fiber material is then transferred to a subsequent swirl-forming device 40. In case of failure of the suction air, the fiber material F is no longer deflected to the suction slot 51, and the suction zone SZ and maintains its position, which it has when leaving the nip Z2 held. D. h the fiber material is transferred in this case without change of direction and without compression on the peripheral surface AF to the nip D of the rotation locking roller 14, from which it is the subsequent swirl-forming device 40 is supplied. If there are no additional monitoring devices for the detection of the failure of the suction air, yarn of poorer quality is produced at this spinning station. To prevent this, additional monitoring devices must be installed at each spinning station in this design.

The swirl-forming device 40 consists in the present embodiment of a ring 26 which is fixed to a moving up and down ring rail 25 and on which a rotor 27 rotates. In the center of the ring 26, a, connected to a drive, not shown, spindle 29 is arranged, which is rotatably mounted on schematically indicated bearings 31 on the spinning machine. On the spindle 29, a sleeve 30 is attached, on which the formed yarn FK is wound into a cop 24. The fiber material discharged from the nip D is fed to the rotor 27 via a yarn guide 28. Through the described ring / runner Combination is twisted the fiber discharged from the nip D, whereby it maintains its strength and is wound up as a twisted yarn. On the way between the clamping line D and the yarn guide 28, a sensor 33 may be provided, via which the presence of a yarn can be monitored. The sensor 33 is connected in the present example via the line 34 to a central controller ST, which evaluates the signal and can trigger appropriate displays or warning signals for the operator.

In the discharge region of the suction roller 9 and the rotation locking roller 14, a suction pipe 18 is provided, which is connected to a suction source 22 shown schematically. Once a yarn break between the drafting 1 and the swirl-forming device 40 is formed, which is led out of the drafting broken end is detected and sucked by the vacuum applied in the suction pipe 18. After elimination of any disturbances at the spinning station, the thread or yarn can be manually or automatically threaded back into the rotor and fed back to the sleeve 30 or the partially wound cop for further winding. Of course, a variety of other designs of yarn monitoring are known.

Based on the embodiments of the Fig.3 and Fig.4 the embodiment claimed according to the invention is explained in more detail below.

Fig. 3 and Fig.4 each shows an embodiment according to the Fig.2 with the inventive embodiment of the rotation locking roller in conjunction with the traversing movement.

In the embodiment of Figure 3 are - viewed transversely to the conveying direction - the traversing c and the suction zone SZ with the width s (as in the example of Fig.2 ) aligned with each other in the middle. Ie. the traversing path c and the width s of the suction zone SZ extend symmetrically to a central axis M, which in the present example also represents the axis of symmetry of the suction slot 51. The rotation lock roller 14a has a cylindrical central part ZA with the width b, which is arranged symmetrically to the central axis M. The cylindrical central part ZA is thus also - viewed transversely to the direction of conveyance FS - centrally to the suction slot 51, or compression region V of the suction zone SZ with the width s (eg 1 - 3 mm) arranged. The width b (6 - 10 mm) greater than the width s, so that the, from the compression region V of the suction zone SZ delivered to the nip D fiber material is securely and completely clamped. If the feed point of the fiber material F is within one of the traversing regions h1 or h2 during the traversing movement, then the fibrous material is no longer deflected or drawn toward the suction slot 51 in the event of a drop or failure of the suction effect at the suction slot 51. Ie. it passes without change of direction and uncompressed to the rotation locking roller 14a and is passed there next to the cylindrical center part ZA. This is in the embodiment of Figure 3 shown by a dot-dash line, wherein the supply of the fiber material F is in the range of the reversal point U1 of traversing movement.

Since the rotation locking roller 14a is provided on both sides of the cylindrical central part ZA each with an outwardly angled α angle taper K1, K2, there is no more clamping line D in the region of the cones K1, K2 between the rotation locking roller 14a and the suction roller In the transition from the cylindrical middle part ZA to the cones K1, K2, there is still a small clamping effect which, however, steadily decreases as the fiber material moves farther away from the cylindrical middle part ZA. Due to the elimination of the clamping action by the rotation locking roller 14a in the, provided with a twisted yarn FK existing tensile force is transferred to the portion of the fiber material F, which is located between the output rollers 9, 8 of the distance 1 and the rotation locking roller 14a. However, this section is provided with little or no rotation and therefore has a substantially lower adhesive force than the provided with a twist yarn FK. This results in the described omission of the clamping action by the cylindrical central part ZA to a demolition of the fiber material F in the area between the output rollers 9, 8 of the distance 1 and the rotation locking roller 14a.

As schematically in the Fig.1 shown, then the protruding from the distance 1 end of the suction pipe 18 is detected and sucked. Since the route 1 continues to work, the subsequently delivered uncompressed fiber material is sucked from the suction pipe 18 and fed to a collection point, not shown, under the action of the vacuum source 22. The torn-off end originating from the twisting device 40 is still wound up on the cop.

The absence of the yarn FK is determined via the sensor 33 and transmitted to the controller ST. About the controller ST can then be notified by display on a screen or optical or acoustic means the interruption at the corresponding spinning station, which can then initiate appropriate measures to repair the spinning station.

The inventively proposed training of the rotation locking roller 14a in conjunction with the traversing movement an automatic and automatic interruption of the yarn production is generated without additional monitoring means must be used. The width b of the cylindrical central portion ZA of the rotation locking roller is kept to a minimum possible extent, so that the supply of the fiber material as soon as possible in an interruption of the suction by the traversing movement in the areas h1, h2 passes, in which the clamping action is canceled by the rotation locking roller and an automatic demolition takes place.

By attaching the cones K1, K2 on the cylindrical central part ZA the foreclosure of the compression region V, or the suction zone SZ with respect to the environment following the rotation locking roller 14a is substantially retained.

In Figure 4 a further embodiment is shown, which essentially the same functional sequences as in the example Figure 3 shows. Instead of in Figure 3 shown Konen K1, K2 close in the example of Figure 4 reduced in diameter cylindrical portions Z5 and Z6 with a diameter d1, which is smaller than the diameter d of the central part ZA. Furthermore, the sections Z5, Z6 are followed by further tapered cylindrical sections Z4, Z7 whose diameter d2 is smaller than the diameter d1 of the sections Z5, Z6. This also ensures that no clamping action is exerted on the fiber material of the rotation locking roller 14b, if this is outside the range of the width b of the central part ZA. In the present example this is the range h3. In contrast to the example of Figure 3 is in the example of Figure 4 the traverse path c1 is not arranged symmetrically to the central axis M, but shifted to one side to the left. This unilateral shift can z. B. by an appropriate Training the compression area conditional. Such an embodiment is z. B. in the Figure 4 the published DE-44 48 021 been shown.

In the further 4a will be a partial view of Figure 4 shown, wherein a rotation locking roller 14c is used, in which instead of the on both sides of the cylindrical central portion ZA subsequent two reduced diameter cylindrical sections Z5, Z4, and Z6, Z7 respectively only a cylindrical portion Z8, or Z9, each having a reduced Diameter d4 connects. Ie. the diameters d4 of the sections Z8, Z9 are smaller than the diameter d of the central part ZA. The other elements correspond to those in Figure 4 shown and described elements, which will not be discussed in more detail here.

In normal operation, the fiber material F is displaced by the suction on one side in the direction of the suction slot 51 and compressed, as indicated by arrows. Upon failure of the suction effect, when the fiber material passes during the traversing in the area h3, eliminates the clamping action by the rotation locking roller 14b, which leads to the previously described outline and the subsequent measures. Here is the description for example the Figure 3 directed. Also by the formation of the rotation locking roller 14b of the compression area is sufficiently sealed off from the environment following the rotation locking roller, so that no undesirable counterflow of air.

It is also possible to provide more than two stepwise graduations following the cylindrical central part ZA of the rotation locking roller 14b.

Claims (8)

Drawframe (1) of a spinning machine with an upstream traversing device (20), via which the fiber material (F) with a laterally to the conveying direction (FS) of the fiber material traversing traversing movement (c, c1) is fed to the drafting system and with a subsequent compression device (9, 16, 50), which comprises a circulating, pressurized with negative pressure compression means (9), which is provided with a suction zone (SZ), to which, the drawn from drafting material is attracted under the action of a suction air flow, wherein the suction zone with over on the Perimeter (AF) of the compaction means distributed perforations (O) is provided and following the suction zone (SZ) a rotation locking roller (14, 14a, 14b, 14c) is provided which forms a nip (D) with the compression means (9), from which the fiber material is fed to a subsequent swirl-forming device (40), characterized in that - in the direction of the axis of rotation (14) of the rotation lock alze (14a, 14b) - the rotation lock roller has a cylindrical, the nip forming portion (ZA), to which in each case to the ends of the rotation locking roller projecting portions (K1, K2, Z4 to Z7, Z8, Z9) connect, which reduce stepwise or continuously in diameter to the ends, wherein the width (b) of the cylindrical portion (ZA) of the rotation locking roller is greater than the width (s) of the suction zone (SZ) and - seen in the conveying direction (FS) of the fiber material - at least one of the reversal points (U1, U2) of the traversing path (c, c1) outside the cylindrical section (ZA) of the rotation-locking roller and within a section (K1, K2, Z4 to Z7; Z8, Z9). Drawframe of a spinning machine according to claim 1, characterized in that the width (b) of the cylindrical portion (ZA) of the rotation locking roller (14a, 14b, 14c) is smaller than the path (c) of the traversing movement. Drafting of a spinning machine according to one of claims 1 or 2, characterized in that the cylindrical portion (ZA) of the rotation locking roller (14a, 14b, 14c) is between 6 and 10 mm. Drawframe according to one of claims 1 to 3, characterized in that the rotation-locking roller (14a) with on both sides of the cylindrical portion (ZA) subsequent, conically extending portions (K1, K2) is provided, respectively towards the ends of the rotation locking roller rejuvenate. Drawframe according to claim 4, characterized in that the taper angle of the conical sections is between 1 ° and 20 °. Drawframe according to one of Claims 1 to 3, characterized in that at least one cylindrical section (Z4, Z5, Z6, Z7, Z8, Z9) has a smaller section on both sides of the central cylindrical section (ZA) of the rotation-locking roller (14b, 14c) Diameter (d1, d2, d4) as the middle section connects. A rotation lock roll for use on a drafting system (1) with a compacting device (9, 16, 50) according to any one of claims 1 to 6. Spinning machine with a drafting device and a compacting device (9, 16, 50) according to one of claims 1 to 6.

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