DE102015109644A1 - Sliver guide - Google Patents

Abstract

The invention relates to a sliver guide, in particular on a track, carding machine or comber, with an elongate base body (2) having a guide which is formed in and / or on a lateral surface (3) of the base body (2) and the two in axial direction of the base body (2) spaced guide surfaces (4a, 4b) to a on the main body (2) passing by sliver (6) between the guide surfaces (4a, 4b) to lead, and with a bearing (5), by means of the base body (2) is mounted, so that the base body (2) is rotatable about its axial axis. According to the invention, the guide surfaces (4a, 4b) extend only partially around a circumference of the base body (2) and are spaced apart from each other to receive a flat sliver (6) therebetween, the spacing of the two guide surfaces (4a, 4b) in Circumferential direction of the base body (2) decreases continuously.

Description

The present invention relates to a sliver guide, in particular on a track, carding machine or comber, with an elongated base body. Furthermore, the sliver guide comprises a guide which is formed in and / or on a lateral surface of the main body and which has two guide surfaces spaced apart in the axial direction of the main body in order to guide a sliver passing between the guide surfaces on the main body. The base body is further mounted in a bearing, so that the base body is rotatable about its axial axis.

From the US 3,130,453 A a cylindrical sliver guide is known which has a groove with a constant depth and an arcuate cross section, wherein the cross section can be varied uniformly. The groove extends once around the sliver guide around. The sliver guide is rotatable, so that a passing sliver different parts of the groove can be turned off. Depending on which portion of the groove is turned to the passing sliver, the sliver is compressed more or less. If the sliver guide is twisted so that a region having a smaller cross section of the groove comes into contact with the sliver, the sliver is compressed more and becomes narrower. When the sliver guide is rotated so that the sliver comes into contact with a portion of the groove having a larger cross section, it is less compressed and becomes wider. A disadvantage of such a sliver guide is that each cross-section of the groove is double. Since the groove is circumferentially closed (ie reconnects to itself in the circumferential direction) and the groove has to be widened again when it becomes narrower in order to join itself, each cross section occurs twice. Thus, portions of the groove are duplicated, namely at a particular location and at an opposite location. Such a sliver guide is thus ineffective and not clearly associated with a particular position and an associated width.

The object of the invention is therefore to provide a sliver guide whose effectiveness and clarity is increased.

The invention is achieved by a sliver guide with the features of the independent claims.

Proposed is a sliver guide, in particular on a track, carding or combing machine, with an elongated body. Furthermore, the sliver guide comprises a guide which is formed in and / or on a lateral surface of the main body and which has two guide surfaces spaced apart in the axial direction of the main body. For example, the guide may be formed as a groove in the lateral surface of the main body. Thus, the flanks of the groove are the guide surfaces and part of the body. Additionally or alternatively, the guide surfaces could be arranged on the lateral surface. For example, the guide surfaces could be formed by means of a band-shaped material and arranged on the lateral surface of the base body. Between the guide surfaces a passing on the body sliver is guided. In this case, the sliver is in the intended use of the sliver guide on the lateral surface of the body. The spreading sliver flows between the guide surfaces, so that it is guided in particular on both sides by a respective guide surface and preferably limited in the axial direction of the body. In particular, the guide and in particular the guide surfaces serve to reduce the spread fiber sliver in width. The width of the fiber sliver emerging from the sliver guide is dependent on the distance between the two guide surfaces on which the sliver is passed between the guide surfaces. The distance between the two guide surfaces is in particular not constant, but varies over the circumference of the body. Furthermore, the sliver guide comprises a bearing, by means of which the main body is mounted, so that it is rotatable about its axial axis. Thus, also the guide and in particular the guide surfaces can be rotated, so that in a simple way another area of the guide and in particular the guide surfaces are brought into contact with the passing sliver. For example, if the incoming sliver is to be reduced in width, the base body can be rotated so that the sliver comes into contact with areas of the guide surfaces, which have a smaller distance from each other. By means of the guide and in particular of the guide surfaces, however, the sliver can also be guided for subsequent processing to a defined point, if, for example, the two guide surfaces have different inclines and / or contours.

According to the invention, the distance of the two guide surfaces in the axial direction of the base body decreases continuously in a circumferential direction about the main body. Thus, the guide and in particular the two guide surfaces each distance only once. The two guide surfaces have at their ends assigned to one another, ie, the two ends of the two guide surfaces, which are arranged at an equal angle of the circumference, a maximum distance. At the two other ends of the two fins, which are also assigned to each other, have the two fins the smallest distance. In between, the distance becomes continuously smaller, so that preferably no distance occurs twice. As a result, the effectiveness is increased, since an expansion of the guide surfaces in the circumferential direction around the main body can be better utilized, especially if no distance occurs twice, no areas of the guide surface are wasted.

Due to the distance between the two guide surfaces, the fiber sliver guided between the guide surfaces can be adjusted in its width. The two fins compress, depending on their distance, the incoming spreading sliver in its width. The fact that the distance between the two guide surfaces always decreases and therefore no distance occurs twice, a larger distance range can be achieved. The distance range is the difference between the greatest distance and the smallest distance. The sliver guide becomes more effective because in the prior art each distance value occurs twice.

In addition, the guide surfaces extend only partially around a circumference of the body. This simplifies the manufacturing process of the guide surfaces. If the baffles are formed, for example, by the flanks of a groove, the groove does not have to be milled around the entire circumference. On the other hand, if the guide surfaces are arranged on the lateral surface of the base body, for example by means of a band-shaped material, this also reduces the production costs. Another advantage is that in the only partial formation of the guide surfaces, the sliver guide and in particular the main body can be arranged closer to subsequent processing points of the sliver.

An advantageous development of the invention is when the sliver guide has a Bandumlenkstelle by means of which the incoming sliver can be deflected. In an intended direction of the sliver, the Bandumlenkstelle is arranged in front of the main body. Additionally or alternatively, a Bandumlenkstelle can be arranged after the base body. Thus, the incoming sliver can be controlled over the body, in particular between the guide surfaces, passed. Additionally or alternatively, the incoming sliver can also be spread at the Bandumlenkstelle. As a result, the quality of the sliver can be increased since a prior spreading of the sliver and subsequent compression, in particular by means of the guide surfaces, increases the homogeneity of the sliver. Previously occurring thin and thick areas flow into each other, so that the density of the individual fibers is uniform in individual areas of the sliver.

Furthermore, it is advantageous if the base body is rotationally symmetrical about its axial axis. Thus, the base body always has the same profile even when rotated. This ensures that the sliver is always passed in the same way over the lateral surface of the body.

It is also advantageous if the base body is cylindrical. This simplifies a manufacturing process of the main body.

It is also advantageous if the lateral surface of the base body is convex and / or concave. Since, in general, the guide surfaces only have effects on edge regions of the sliver, it is advantageous if the lateral surface between the guide surfaces is concave. Thus, the sliver surface running on the lateral surface is also compressed in this area, since it strives towards the lowest point of the concave lateral surface. By means of a convex lateral surface, the sliver can be loosened because it strives away from the highest point of the lateral surface and is thus pulled apart. This increases the quality of the sliver.

In addition, it is advantageous if the sliver guide has a drive by means of which the base body is rotatable about its axial direction. The drive can be designed as an electric drive, for example as a servomotor, as a pneumatic and / or as a hydraulic drive. By means of the drive, the basic body can be turned particularly precisely and quickly. If, for example, a degree of compression of the fiber sliver, in particular before the sliver guide, is measured continuously, the main body can be adapted to places where the sliver has a different compression by the base body is rotated exactly at these points accordingly, so that the Compression is compensated at these points. The sliver guide has suitable sensors to measure the degree of compression. In addition, the sliver guide has a control unit which evaluates the sensor data and drives the drive accordingly. This increases the quality of the sliver by the homogeneity of the sliver is increased.

Moreover, it is advantageous if the sliver guide has a display element by means of which an orientation of the base body can be displayed. Thus, for example, the current orientation of the base body can be identified for a maintenance personnel. In particular, the maintenance staff knows at which point the sliver is passed between the baffles, and what distance the baffles have this position. In addition, the orientation can be logged, so that for a later use of the sliver guide on the basis of the data advantageous setting, in particular rotation of the body can be reset.

It is also advantageous if the base body has a latching element, by means of which the base body can be fixed in an orientation. This can be prevented that, for example, by vibrations of the machine twisted the main body.

A particularly advantageous embodiment of the invention is when the two guide surfaces form helices on the lateral surface of the body so that they run together to a center of the body out. In this case, the two baffles may be formed opposite to usual, i. one guide surface is right-handed and the other is left-handed. Each guide surface thus forms a helix on the lateral surface of the main body. In particular, the pitch of the helices around the circumference of the body can be constant. The slope of the helices may also be variable. By means of the helices of the two guide surfaces of the acting on the sliver distance between these two is particularly easy to adjust. The two helical guide surfaces can also have different slopes. As a result, the sliver can be moved in the axial direction of the body.

Furthermore, it is advantageous if the two guide surfaces are mirror-symmetrical. The guide surfaces are formed mirror-symmetrically, for example, to a cross-sectional area of the base body. Thus, the two sides of the sliver can be performed the same at the two baffles.

Furthermore, it is advantageous if the two guide surfaces each have an angle between 20 ° and 70 °, in particular between 40 ° and 60 °, relative to the circumferential direction of the base body. Since the passing sliver is aligned parallel to the circumferential direction of the body, the sliver has the same angle to the guide surfaces. By means of a smaller angle, the sliver can be performed gently. With a higher angle, however, the sliver can be compressed more.

Likewise, it is advantageous if the guide surfaces extend between 150 ° and 330 °, preferably 180 °, around the circumference of the main body. Extend the fins further around the circumference of the body, a larger distance range can be formed with the same slope of the fins. The distance range here is the difference between the largest distance and the smallest distance between the guide surfaces. If the guide surfaces are formed at a smaller angle around the circumference of the main body, this simplifies a manufacturing process.

It is also advantageous if the guide surfaces have an angle between 0 ° and 30 ° relative to a radial direction of the base body. Preferably, the baffles are inclined away from the sliver passed through between the baffles. When leaving the sliver of the guide surfaces, the sliver thus does not slip over an edge which forms an edge of the guide surfaces. This reduces the friction between the sliver and the edges, resulting in less wear.

If the main body and the guide surfaces are integrally formed, this also brings advantages. As a result, the main body and the guide surfaces can be produced particularly quickly in a few steps. For example, the main body can be cast with the guide surfaces, so that the sliver guide can be made particularly fast and inexpensive.

In order to reduce friction between the passing sliver and the lateral surface and / or the guide surfaces, it is advantageous if the base body and / or the guide surfaces are coated with a surface coating. As a result, the durability of the sliver guide is extended and the risk of damage to the sliver is reduced. The surface coating can be formed by a chromium layer, for example, has small elevations to effect a lotus flower effect. The surveys can be formed, for example, spherical.

Furthermore, it is advantageous if a maximum distance of the two guide surfaces in the axial direction of the base body is between 10 cm and 15 cm. Additionally or alternatively, the minimum distance between the two guide surfaces in the axial direction of the base body is between 2 cm and 6 cm. The maximum distance determines which width the incoming sliver may have to be guided by the sliver guide. The minimum distance determines the width that the emerging sliver has minimal.

In addition, a system of sliver guides with at least one sliver guide according to the foregoing description is proposed. According to the invention, the system has a plurality of sliver guides.

For example, if it is required that the sliver is to be guided over long distances, several sliver guides can be arranged one behind the other. For example, one sliver guide may compress the sliver and another sliver guide may displace the sliver in an axial direction of the main body of the sliver guide.

Further advantages of the invention are described in the following exemplary embodiments. It shows:

1 a perspective view of a sliver guide with two guide surfaces,

2 a side sectional view of a sliver guide and a Bandumlenkstelle, and

3 a plan view of a rolled surface of a sliver guide with two guide surfaces.

In 1 is a perspective view of a sliver guide 1 shown. The sliver guide 1 includes a main body 2 with a lateral surface 3 , as well as two fins 4a . 4b and a warehouse 5 , The main body 2 can be rotationally symmetrical. Preferably, the main body 2 , as in this embodiment, be cylindrical. The main body 2 but can also be a concave and / or convex lateral surface 3 exhibit. In particular, the area of the lateral surface 3 between the fins 4a . 4b concave and / or convex, since in this area a not shown here sliver 6 (see. 2 ) is passed. The sliver 6 is doing over the lateral surface 3 passed away, with the sliver 6 the lateral surface 3 only in small areas (cf. 2 ) in the circumferential direction of the body 2 wraps. The sliver 6 is doing on its sides at the respective baffles 4a . 4b in an axial direction of the main body 2 limited. In particular, the sliver becomes 6 reduced in width when the incoming and flat spread sliver 6 has a greater width than the distance of the guide surfaces 4a . 4b at the point where the sliver 6 with the fins 4a . 4b comes into contact. The sliver 6 can be at the fins 4a . 4b also in the axial direction of the body 2 be moved.

By means of the warehouse 5 is the main body 2 rotatably mounted about its axial axis. Advantageously, the bearing 5 at both ends of the body 2 designed to allow stable storage of the body. The main body 2 is rotatable about the direction of rotation DR. For example, the main body 2 be rotated in a clockwise direction, so that, in this figure at an upper side of the base body 2 , the distance between the fins 4a . 4b gets bigger. A sliver passed through at this point 6 is less compressed in its width and / or out. Will, however, the main body 2 turned counterclockwise, is, again at a top of the body 2 , the distance between the fins 4a . 4b reduced. A sliver passing through at this point 6 is thus more guided and / or more compressed in its width, so that the exiting sliver 6 has a smaller width.

In 2 is a side sectional view of a sliver guide 1 with a band deflection point 7 shown. The sliver guide again comprises a main body 2 with a lateral surface 3 , Over the lateral surface 3 is a sliver 6 guided in an area with the lateral surface 3 has a contact. The sliver 6 further leads between two fins 4a . 4b (see. 1 ), in this embodiment, only the guide surface 4b is shown. Furthermore, the guide surface 4b 270 ° around the circumference of the body 2 educated. Thus, the main body 2 be rotated by an angular range of 270 ° about its axial axis in the direction of rotation DR, so that the sliver 6 still guided. In this embodiment, for example, the main body 2 rotated by about 90 ° counterclockwise and / or about 180 ° in a clockwise direction, wherein the sliver 6 still from the fins 4a . 4b is guided.

In front of the main body 2 or against a designated running direction LR of the sliver 6 is the tape redirection point 7 arranged. Alternatively, a Bandumlenkstelle 7 also after the main body 2 be arranged. This may be similar dimensions as the main body 2 in particular, the band deflection point 7 also an elongated, cylindrical body over which the sliver 6 is directed. However, the band deflection point can also have a concave and / or convex cross section. The band deflection point 7 Can also be used as a guide for the sliver 6 serve. The band deflection point 7 however, has no guide surfaces 4a . 4b in particular, this has only one lateral surface. The sliver 6 however, is advantageously shown as in the embodiment, first under the tape deflection point 7 and then over the main body 2 guided, so that the sliver 6 between these two points "spanned" is. Alternatively, the sliver could 6 also first about the band deflection point 7 and then under the body 2 be guided, wherein the sliver is also "spanned".

In 3 is an unrolled lateral surface 3 of a basic body 2 (see. 1 ) with two fins 4a . 4b shown. The main body 2 is thus shown areally. The extent of the lateral surface 3 in the circumferential direction is thus the complete circumference of the body 2 , It should be noted that one side connects directly to the other side in the circumferential direction.

The two fins 4a . 4b are thus no longer in this view as in the 1 helically formed, but run together at an angle α. The angle α is between the fins 4b and the circumferential direction is formed. The guide surface 4a has the same absolute angle, since both fins 4a . 4b are mirror-symmetrical to each other. Alternatively, could also be a guide surface 4a . 4b have a larger angle α, so that both fins 4a . 4b are no longer mirror-symmetrical to each other.

The two fins 4a . 4b have a maximum distance in the axial direction 8th and a minimum distance 9 on. In the circumferential direction, the distance between the two guide surfaces decreases 4a . 4b from the maximum distance 8th up to the minimum distance 9 continuously off. In this embodiment, the distance becomes linearly smaller. The distance could also be non-linearly smaller, for example, exponential, logarithmic, parabolic and / or hyperbolic.

The present invention is not limited to the illustrated and described embodiments. Variations within the scope of the claims are also possible as a combination of features, even if they are shown and described in different embodiments.

LIST OF REFERENCE NUMBERS

1

Sliver guide

2

body

3

lateral surface

4

baffle

5

camp

6

sliver

7

webbing deflection

8th

maximum distance

9

minimum distance

DR

 direction of rotation

LR

 direction

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 3,130,453 A [0002]

Claims (15)

Sliver guide, in particular on a track, carding machine or combing machine, with an elongate body ( 2 ), which has a guide, which in and / or on a lateral surface ( 3 ) of the basic body ( 2 ) is formed and the two in the axial direction of the base body ( 2 ) spaced guide surfaces ( 4a . 4b ) to a on the body ( 2 ) passing sliver ( 6 ) between the fins ( 4a . 4b ) and with a warehouse ( 5 ), by means of which the main body ( 2 ) is stored, so that the main body ( 2 ) is rotatable about its axial axis, characterized in that the guide surfaces ( 4a . 4b ) only partially around a circumference of the basic body ( 2 ) and at a distance from each other, in order between them a flat spread sliver ( 6 ) and that the distance between the two guide surfaces ( 4a . 4b ) in the circumferential direction of the main body ( 2 ) decreases continuously. Sliver guide according to the preceding claim, characterized in that the sliver guide ( 1 ) a band deflection point ( 7 ), which in an intended direction of travel (LR) of the sliver ( 6 ) in front of the main body ( 2 ) is arranged and by means of the incoming sliver ( 6 ) can be redirected and / or spread. Sliver guide according to one or more of the preceding claims, characterized in that the basic body ( 2 ) Is formed about its axial axis rotationally symmetrical, in particular cylindrical, convex and / or concave. Sliver guide according to one or more of the preceding claims, characterized in that the sliver guide ( 1 ) has a drive, by means of which the basic body ( 2 ) is rotatable about its axial direction. Sliver guide according to one or more of the preceding claims, characterized in that the sliver guide ( 1 ) has a display element, by means of which an orientation of the main body ( 2 ) can be displayed. Sliver guide according to one or more of the preceding claims, characterized in that the basic body ( 2 ) has a latching element, by means of which the basic body ( 2 ) can be fixed in an orientation. Sliver guide according to one or more of the preceding claims, characterized in that the two guide surfaces ( 4a . 4b ) in particular opposite conventional helices on the lateral surface ( 3 ) of the basic body ( 2 ), so that these become a center of the basic body ( 2 ) run together. Sliver guide according to one or more of the preceding claims, characterized in that the two guide surfaces ( 4a . 4b ) are mirror-symmetrical. Sliver guide according to one or more of the preceding claims, characterized in that the two guide surfaces ( 4a . 4b ) in each case to the circumferential direction of the base body ( 2 ) have an angle (α) between 20 ° and 70 °, in particular between 40 ° and 60 °. Sliver guide according to one or more of the preceding claims, characterized in that the guide surfaces ( 4a . 4b ) between 150 ° and 330 °, preferably 180 °, around the circumference of the main body ( 2 ). Sliver guide according to one or more of the preceding claims, characterized in that the guide surfaces ( 4a . 4b ) to a radial direction of the main body ( 2 ) have an angle between 0 ° and 30 °. Sliver guide according to one or more of the preceding claims, characterized in that the basic body ( 2 ) and the fins ( 4a . 4b ) are integrally formed. Sliver guide according to one or more of the preceding claims, characterized in that the basic body ( 2 ) and / or the fins ( 4a . 4b ) are coated with a surface coating. Sliver guide according to one or more of the preceding claims, characterized in that a maximum distance ( 8th ) of the two fins ( 4a . 4b ) in the axial direction of the main body ( 2 ) between 10 cm and 15 cm and / or the minimum distance ( 9 ) of the two fins ( 4a . 4b ) in the axial direction of the main body ( 2 ) is between 2 cm and 6 cm. System of sliver guides with at least one sliver guide ( 1 ) according to one or more of the preceding claims, characterized in that the system comprises a plurality of individual sliver guides ( 1 ) having.

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