EP0071893A2 - Method and device for cleaning open-end spinning rotors - Google Patents

Abstract

In a method for cleaning spinning rotors for open-end spinning, a cleaning device (15) is placed on the opened rotor housing (13) and used to generate at least one rotating air jet which essentially acts on the fiber collecting groove of the rotor. Before generating the air jet, the rotor (11) is shut down and the cleaning device (15) is placed on the rotor housing (13) in such a way that between the end face of a blow head (18) generating the air jet and the free edge (34) of the rotor ( 11) forms a round gap (35). During a suction process, air is first sucked through the gap (35) from the rotor housing opening (14) through the interior of the rotor (11). The blow head (18) is then immersed in the interior of the rotor (11) and set in rotation so that the rotating air jet is formed. The suction process is maintained during this cleaning stage. The application also relates to a device for performing the method.

Description

The present invention relates to a method for cleaning spinning rotors for open-end spinning, each rotor of which is located in a rotor housing with a rotor housing opening provided for external suction, in which method the rotor housing of the rotor to be cleaned is opened and opened by a this rotor housing mounted cleaning device is covered, and the cleaning device generates by means of a rotatable blower body at least one rotating air jet which essentially acts on the collecting groove of the rotor.

German Offenlegungsschrift No. 26 13 180 discloses an open-end spinning machine in which the means for cleaning the spinning rotor contain a combined blowing and suction device which can be moved towards the latter. In addition, the suction part has a flange, which rests in the manner of a cover on the housing surrounding the spinning rotor. The blowing out and suctioning off the spinning rotor. In US Pat. No. 4,211,063, two air jets are shown which blow air against the collecting groove or into the interior of the rotor which is in rotation at predetermined, different angles. According to these two patents, the spinning rotors are rotating during the cleaning process. This means that the impurities accumulated in the collecting groove of the rotor adhere relatively firmly as a result of the centrifugal force. This makes it difficult to get proper cleaning.

German Offenlegungsschrift No. 26 48 066 shows a method in which a rotating cleaning brush is immersed in the rotating rotor for carrying out the rotor cleaning and comes into contact with its inner surface and in particular also with the collecting groove. According to German Offenlegungsschrift No. 24 10 269, a flexible probe is provided as a mechanical cleaning element for moving into the spinning rotor to be cleaned. When using brushes, the relatively strong adhesion of the contaminants due to the centrifugal force plays a subordinate role. However, there is a risk that - when using such solid cleaning agents, the inner wall of the rotor will be scratched. It should also be added that this danger also exists when using scrapers. This affects the uniformity of the fibers to be spun collected in the collecting groove of the rotor. Fibers and thread remnants can also get caught on the brushes or wind up on them, reducing their effectiveness. In addition, the wear of brushes is relatively high.

The above disadvantages are to be avoided according to the present invention. This is characterized in that the rotor is stopped prior to generating the air jet, that when the cleaning device is placed on the rotor housing, a round gap located between two parallel planes is located between the end face of a blow head facing the rotor and the free edge of the rotor through which air is sucked from the rotor housing opening through the interior of the rotor in a suction process, and that the blow head is then immersed in the interior of the rotor and set in rotation and, while the suction process is maintained, forms the rotating air jet.

The invention also relates to a cleaning device for carrying out the method, which comprises a cleaning cover which can be placed on the rotor housing of the rotor to be cleaned and the rotatable blow head, the axis of rotation of which essentially coincides with that of the rotor, and which is characterized in that a through the cleaning cover Suction channel is provided that the blow head parallel to its axis of rotation from its working position, in which its end facing the rotor is located near the free edge of the rotor and with its free edge forms the round gap, in a second working position, in which the blow head is immersed in the interior of the rotor, is movable, and that it has at least one cleaning channel which serves to generate an air jet and which is connected to a compressed air line which is used for the optional supply of Compressed air is used for the cleaning duct.

The thorough cleaning resulting from this invention, in addition to eliminating the centrifugal force already mentioned, is essentially due to the fact that the fibrous impurities accumulated in the collecting groove are transported away by the suction process that occurs first and then the relatively strongly adhering impurities consisting of fine dust particles through a sharp, ie the shortest possible jet should be blown away. In this way, a cleaning process that is specific and effective for each type is provided for both types of impurities.

• Fig. 1 ein Längsschnitt eines Spinnrotors und einer Reinigungsvorrichtung, der die Position des Blaskopfes während des Saugvorganges zeigt,
• Fig. 2 ein Längsschnitt, der die Position des Blaskopfes während des Blasvorganges zeigt und
• Fig. 3 ein Querschnitt eines Blaskopfes, welcher verschiedene Luftkanäle zeigt.

The invention will be explained in more detail below using an exemplary embodiment and the drawing. In the latter is

• 1 shows a longitudinal section of a spinning rotor and a cleaning device, which shows the position of the blow head during the suction process,
• Fig. 2 is a longitudinal section showing the position of the blow head during the blowing process and
• Fig. 3 is a cross section of a blow head, which shows different air channels.

1 and 2, a spinning rotor 11 is shown, which is rotatably supported by an axle bearing 12. The spinning rotor 11 is located inside a rotor housing 13. The latter is open with a rotor housing Provide 14, which is provided in normal operation for the external suction for sliver conveyance. The rotor housing 13 is normally closed with a cover during operation. In the drawing, however, this cover is not shown and a cleaning device 15 is placed on the rotor housing 13 in its place. The device 15 comprises a suction line 16, a cylinder 17, a blow head 18 and a cleaning cover 19. The latter can be placed on the open rotor housing 13 with a tight fit. The blow head 18 is supported by a shaft 21 at one end and the shaft 21 is rotatably supported in bearings 22. The axes of rotation of the rotor 11 and the shaft 21 coincide. The bearings 22 are carried by a piston 23 which can be displaced in the cylinder 17 in its axial direction. By means of a return spring 24, the piston 23 is exposed to a prestress directed to the left, ie to a prestress directed against the end face of the cylinder 17 facing away from the blow head 18.

In the blow head 18 there is a cleaning channel 25 for generating an air jet, which ends at one end in a longitudinal bore 26 provided in the shaft 21. In addition, drive channels 27 formed by air lines are provided, which serve to set the blow head 18 in rotation. The channels 27 extend radially outward from the longitudinal bore 26 in opposite directions and bend at right angles to the cylindrical surface of the blow head 18 in mutually opposite directions. As shown in FIG. 3, these angled channel sections 27 'of the drive channels 27 run out at their exit point the blow head 18 approximately tangential to its surface. The air emerging from the duct pieces 27 'must have at least one movement component tangential to the surface of the head 18 in order to be able to set the blow head 18 in rotation.

The cross section shown in FIG. 3 of a blow head 18 in a plane perpendicular to its axis of rotation and thus also to the shaft 21 shows a possible arrangement of channels. There are two drive channels 27 with the channel sections 27 '. They proceed in the manner just described above. In contrast to FIG. 2, a single cleaning channel is not provided, but there are three cleaning channels 25 arranged around the longitudinal bore 26 at equal angular distances from one another, all of which essentially against the collecting groove 32 of the spinning rotor 11, which is particularly soiled by pieces of fiber and dust particles is exposed. If desired, cleaning channels 33 designed as air lines can additionally be provided. These serve to give the rotor edge 34 of the rotor 11, to which fibers adhere relatively strongly, a particularly vigorous cleaning. For this purpose, the cleaning channels 33 are directed towards the edge 34. On the end face of the cylinder 17 facing away from the blow head 18 there is a compressed air line 29 which serves for the optional introduction of compressed air into the interior of the cylinder 17.

For the cleaning of the spinning rotor 11 this, for example by pivoting away from it driving, is not ge showed drive means and possibly by braking, first brought to a standstill and the cover, not shown in the drawing, of the rotor housing 13 which is normally covered during operation, is pivoted open. Thereupon the cleaning device 15 is brought up to the rotor housing 13 and the cleaning cover 19 is applied to it, whereby it sits on the housing 13 with a full seat and covers it. In this working phase, the piston 23, which is biased by the return spring 24, is in its reset position, shown in FIG. 1. In this, the end face of the blower body 18 facing the rotor 11 forms a round gap 35, for example a few millimeters thick, with the edge 34 of the rotor 11. The gap 35 is located between two parallel planes, one of which is defined by the rotor edge 34 and the other by the end face of the blow head 18 facing the rotor 11.

Experience shows that air, as indicated by arrows, from the suction line 16 of the cleaning device 15, from the rotor housing opening 14 through the rotor housing 13, through the gap 35 between the rotor edge 34 and the blow head 18 and through the interior of the rotor 11 flows through and flows through the suction line 16. Since the rotor 11 is at a standstill during this process, this air entrains, in particular, the impurities consisting of fiber pieces that lie in a ring in the collecting groove 32 and no longer adhere by centrifugal force. In this case, these are led away through the gap 35 and through the suction line 16.

Subsequently, compressed air is introduced into the interior of the cylinder 17 through the compressed air line 29. This causes a pressure on the piston 23, which is directed against the bias generated by the return spring 24 and is greater than this. As a result, the piston 23 is moved to the right. The blow head 18 is taken along so that it dips into the interior of the rotor 11, assuming the position shown in FIG. 2. At the same time, compressed air penetrates into the longitudinal bore 26 and from there into the cleaning channel 25 or into the channels 25 and into the drive channels 27 with the channel sections 27 ′. The air flowing through the channels 27, 27 'sets the blower body 18 in rotation and the air flowing through the channels blows out the last remnants of the impurities remaining in the spinning rotor 11 or the collecting groove 32. These are primarily fine dust particles which adhere relatively firmly in the groove 32. In order to remove these, a strong and sharp air jet must be formed through the channels 25. These dust particles are also carried away by the suction channel 16.

In a modified embodiment, the drive channels 27 with the sections 27 ′ are so far against the free end of the blow body 18 (to the right in FIG. 2) that they also blow into the interior of the rotor 11, in particular into the collecting groove 32 and thus also contribute to its cleaning. In this case, they serve both to drive the blow head 18 and to clean the collecting groove 32, but can also contribute to cleaning the rotor edge 34.

The air jet is sharper the shorter it is. For this reason, the air outlet points of the channels 25 are located on the lateral surface of the blow head 18, which in the example shown is of essentially circular cylindrical shape. Therefore, if the diameter of the lateral surface is chosen to be as large as possible so that the space between it and the rotor edge 34 is small, the air outlet points are brought so close to the parts of the rotor 11 to be cleaned, in particular to the collecting groove 32, as this is practically possible.

A further, further improvement in the cleaning of the rotor 11 is obtained if the strength of the rotating air jet is varied, in particular if it is formed by successive air pulses. In an advantageous embodiment, three successive blowing pulses are generated for cleaning the rotor 11. Depending on the material and degree of contamination, the duration of these blowing pulses or the duration of the generation of each of these pulses is between 0.3 and 1.5 seconds and the pauses between the blowing pulses are between 0.2 and 0.4 seconds.

A pulsating air jet has a stronger cleaning power than an air jet of the same size but of constant strength. In particular, a pulsating air jet in the example shown in FIGS. 1 and 2 also causes a reciprocation of the piston 23 in the cylinder 17 and thus a change in the immersion depth of the blow head 18 in the rotor 11. This change in the immersion depth causes, in addition to the effect of pulsating air jet, a further, additional improvement of the Cleaning, so that in the embodiment of FIGS. 1 and 2, the pulsating air jet is of very particular advantage.

A pulsating air jet can be generated, for example, by means of a controllable valve 36 which is installed in the air pressure line 29 and is opened and closed again in accordance with the desired time intervals.

In a further advantageous modification of the embodiment according to FIGS. 1 and 2, a bore is provided which extends from the atmosphere to the chamber containing the blow head 18. The bore is dimensioned so that it allows a steady flow of air into the chamber under the influence of the suction applied via the channel 16. The air flow around the die is therefore directed outward from the chamber, reducing the tendency for dirt to be drawn into the chamber by the rotor during die movements.

Claims (14)

1. A method for cleaning spinning rotors for open-end spinning, of which each rotor is located in a rotor housing with a rotor housing opening provided for external suction, in which method the rotor housing of the rotor to be cleaned is opened, covered by a cleaning device placed on this rotor housing and the cleaning device generates by means of a rotatable blower body at least one rotating air jet which essentially acts on the collecting groove of the rotor, characterized in that, prior to the generation of the air jet, the rotor (11) is stopped such that when the cleaning device (15) is put on on the rotor housing (13) between the end face of a blow head (18) and the free edge (34) of the rotor (11), a round gap (35) located between two parallel planes is formed, through which air from the - Rotor housing opening (14) through the interior of the rotor (11 ) is sucked through and that the blow head (18) is then immersed in the interior of the rotor (11) and set into rotation and, while the suction process is being maintained, forms the rotating air jet. 2. The method according to claim 1, characterized in that further points of the rotor (11) which require a particularly strong cleaning, from one Air jet are applied. 3. The method according to claim 1 or 2, characterized in that the rotating air jet is changed in its strength. 4. The method according to any one of the preceding claims, characterized in that the rotating air jet is formed from successive air pulses. 5. The method according to claim 4, characterized in that the rotating air jet is formed from three air pulses which are generated during periods of 0.3 to 1.5 seconds each and that between these periods there are pauses of 0.2 to 0.4 Seconds. 6. Cleaning device for performing the method according to claim 1 or 2, which comprises a mountable on the rotor housing of the rotor to be cleaned cleaning cover and the rotatable blow head, the axis of rotation of which coincides essentially with that of the rotor, characterized in that a through the cleaning cover ( 19) leading suction channel (16) is provided that the blow head (18) parallel to its axis of rotation from its working position, in which its end facing the rotor (11) is located near the free edge (34) of the rotor (11) and with its free edge (34) forms the round gap (35), in a second working position, in which the blow head (18) is immersed in the interior of the rotor (11), and that it can generate at least one Air jet cleaning channel (25), which is connected to a compressed air line (29), which serves for the optional supply of compressed air to the cleaning channel (25). 7. Device according to claim 6, characterized in that it comprises a cylinder (17) and a rotatable - and with this cylinder (17) coaxially arranged shaft (21), which shaft (21) at one end the blow head ( 18) carries and is held in a rotary bearing (22) which is carried and displaceable by a piston (23) which is displaceable in the longitudinal direction inside the cylinder (17) in the longitudinal direction thereof, the blow head (18) being separated from the free one Rotor edge (34) forming a gap (35) into the interior of the rotor (11) - can be moved into it. 8. Device according to claim 7, characterized in that the shaft (21) has a central longitudinal bore (26) which opens with its end facing away from the blow head (18) into the cylinder interior that on the end face of the blow head (18) facing away from Cylinder (17) leads the compressed air line (29) into the interior of the cylinder, and that the cleaning channel ^- (25) opens with one of its ends into the longitudinal bore (26). 9. Device according to one of claims 6 to 8, characterized in that the opening of the suction channel (16) in the rotor housing (13) and the rotor housing opening (14) with respect to the rotor (11) are arranged diametrically opposite one another. 10. Device according to one of claims 6 to 9, characterized in that the exit point of the cleaning channel (25) is located at a point on the outer surface of the blow head (18), which is immersed in the interior of the rotor (11) blow head (18) is relatively close to the collecting groove (32). 11. Device according to one of claims 7 to 10, characterized in that the piston (23) against the blow head (18) facing away from the end of the cylinder (17) is elastically biased, and that the pressure through the compressed air line (29) air supplied to the piston (23) is greater than the preload acting on it. 12. Device according to one of claims 7 to 11, characterized in that in order to achieve a rotational movement of the blow head (18) it has at least one drive channel (27) designed as an air channel, which is connected to the longitudinal bore (26) and in which the Air emerging from the drive channel (27) or at least one movement component thereof is directed tangentially with respect to the circular path described by the air outlet point during the rotational movement. 13. The device according to claim 12, characterized in that the air flow formed by the drive channel (27) upon exit from the blow head (18) is directed against points to be cleaned, in particular against the collecting groove (32). 14. The device according to claim 11, characterized in that in the compressed air line (29), the regulating the air flowing through this line (29) serving serving, adjustable valve is present.

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