DE102015106808A1 - Nonwoven funnel for compacting a nonwoven fabric with a guide element - Google Patents

Abstract

The invention relates to a fleece funnel for compacting a nonwoven fabric, in particular on a stretch, carding machine or combing machine, having an input side (2) which is oblong in the x-direction and at which the spread nonwoven fabric enters the nonwoven funnel (1) and one in the z-direction to the input side (2) spaced output side (3), at which the nonwoven as a sliver emerges from the nonwoven funnel (1), with an outlet opening (4) which is arranged on the output side (3) and at least one between input side (2 ) and output side (3) arranged guide surface (5a, 5b) for the nonwoven fabric in order to guide the nonwoven fabric flowing into the fleece funnel (1) in the direction of the exit opening (4). According to the invention, at least one guide element (6, 12) is arranged in an area between the inlet side (2) and the outlet opening (4), which limits a movement of the fiber fleece in the x-direction and / or in the y-direction.

Description

The present invention relates to a fleece funnel for compacting a fibrous web, in particular on a track, carding machine or combing machine. The fleece straightener has an input side which is oblong in the x direction and at which the spread fiber fleece enters the fleece funnel. In the z-direction to the input side, an output side is spaced at which the nonwoven fabric emerges as a sliver from the web straightener. On the output side, an output port is arranged. At least one guide surface is arranged between the input side and output side for the nonwoven fabric in order to guide the nonwoven fabric flowing into the nonwoven funnel in the direction of the outlet opening.

From the DE 102 30 433 A1 is a fleece straightener for band-forming textile machines known. The fleece funnel has a draw-off opening, through which a sliver emerges from the fleece funnel. Impact and / or baffles are arranged on both sides of the discharge opening, wherein the nonwoven fabric is folded by the impact and / or baffles from two sides to the discharge opening. Between two baffles a Stufungsfläche is arranged. A disadvantage of such a fleece funnel is that the nonwoven fabric, which flows from the two baffle and / or guide surfaces to the discharge opening, can slide over the discharge opening and only after an arc passes over the opposing impact and / or guide surface into the discharge opening. A part of the nonwoven fabric thus cooperates with parts of the nonwoven fabric, which come from the respective opposite baffle and / or guide surface. The two parts thereby hinder each other as it flows into the outlet opening. The fiber fleece thus runs uncontrollably in the exhaust opening, whereby the quality of the emerging sliver decreases.

The object of the present invention is therefore to provide a guide element for a fleece funnel, which improves the quality of the emerging sliver.

The object is achieved by a fleece funnel with the features of the independent claim.

A nonwoven funnel is proposed for compacting a fiber fleece, in particular on a stretch, carding machine or combing machine, which has an input side elongated in the x-direction, at which the spread nonwoven fabric enters the fleece funnel. The nonwoven fabric emerges from the nonwoven funnel as a fiber sliver at an exit side which is at a distance from the entry side in the z-direction. In the output side, an output port is arranged. At least one guide surface is arranged between the input side and output side in order to guide the nonwoven fabric flowing into the nonwoven funnel in the direction of the outlet opening. Preferably, two guide surfaces, in each case adjacent to the outlet opening, are arranged in the fleece funnel. These cause the actual funnel function. For example, these may converge towards the exit opening, thereby redirecting the nonwoven fabric impinging on the fins toward the exit opening. The fibrous web compressed into a sliver leaves the nonwoven funnel through the exit opening. The dimensions, in particular the diameter, of the exit opening preferably determine the degree of compression of the nonwoven fabric.

According to the invention, a guide element is arranged in a region between the inlet side and the outlet opening, which delimits a movement of the fiber fleece that is proportional in the x direction. Limiting the movement of the fibrous web, especially when it comes from a baffle, prevents adverse interaction with other parts of the fibrous web. In particular, in the case of two guide surfaces which are respectively adjacent to the exit opening, the parts of the nonwoven fabric coming from the respective guide surfaces are substantially prevented by the guide element from interacting with the respective other part of the nonwoven fabric. In particular, the respective parts do not encounter each other head-on, which would lead to a disordered arrangement of the individual fibers in the non-woven fabric. The guide element is a further element in the process of fiber compression. The non-woven fabric first strikes the at least one guide surface, from where it is conducted in the direction of the exit opening. The guide element forms a boundary, so that the nonwoven fabric more controlled, preferably without the parts of the nonwoven fabric from colliding with each other from different directions, flow into the outlet opening. The introduction of the fiber web into the exit opening is improved, which increases the quality of the emerging sliver.

Additionally or alternatively, a further guide element may be arranged in a region between the inlet side and outlet opening, by means of which a movement of the fiber fleece that is proportional in the y direction is limited. In the fleece funnel, parts of the nonwoven fabric may loop in a yz plane over the exit opening. The loop buckles and flows uncontrollably into the outlet opening. By means of the further guiding element, the loop can be directed in the opposite direction, in particular away from the exit opening, where more space is available in which the loop can expand. Then the loop leads into the exit opening. This prevents the non-woven fabric from buckling. With the additional guiding element, the limited movement in the y-direction, a path difference can be compensated. The path difference arises because a direct path into the exit opening is shorter than a path that leads over the guide surfaces and then into the exit opening. This prevents distortion within the sliver.

An advantageous development of the invention is when the guide element is arranged offset in the y-direction, which is orthogonal to the x and z direction, offset from the outlet opening. The guide element is thus not arranged directly above the outlet opening. This prevents in particular that the guide element itself hinders a direct inflow of the fiber web into the exit opening. In addition, upon impingement of the fibrous web on the baffle, a vortex may form that forms an arc around the exit port. The vortex is formed in particular in the x-y plane. By a displacement of the guide element in the y-direction, this is arranged on an edge of the vortex. The guide element thus acts tangentially on the vortex, which increases the effect of the guide element. The quality of the emerging sliver is increased.

Moreover, it is advantageous if the guide element is designed as a baffle element, which has at least one of the at least one guide surface facing side on which bounce at least parts of the fiber web. A baffle designed as a baffle element limits the movement of the fibrous web in the x direction in a simple manner. The baffle element is an obstacle to the parts of the fibrous web, whereupon they bounce off and / or their movement is limited.

It is also advantageous if the baffle element is prism-shaped. This is a simple form that is easy to manufacture.

Advantageously, the baffle element has a shape tapering in the z-direction. Thus, the shape of the impact element can be adapted to a profile of the fiber web to a sliver. The sliver quality is thus increased.

Furthermore, it is advantageous if the impact element is tapered in its x-dimension. In particular, when the impact element is tapered towards the exit opening, the parts of the fiber web which come from a guide surface from the x-direction collide in such a way from the impact element that the parts of the fiber web are diverted in the direction of the exit opening. An inflow of the fiber web into the exit opening is thus supported, which increases the quality of the sliver.

It is also advantageous if the impact element is tapered in its y-dimension. In particular, when the baffle element is tapered away from the exit opening, an influence of the baffle element on the parts of the nonwoven fabric which is directly, i. without encountering a guide surface, flow into the outlet opening, reduced. As a result, the quality of the emerging sliver is increased.

It is also advantageous if the at least one side of the impact element, on which parts of the nonwoven fabric rebound, is straight and / or concave. The parts of the fibrous web coming from the guide surface may be arranged in parallel. Then a straight side of the baffle may be used to deflect the parallel portions of the fibrous web to the same extent, which in turn results in parallel portions of the fibrous web which then flow toward the exit port. However, it may also be possible that the parts of the fiber fleece that come from the guide surface are not parallel to one another, that is to say have different directions to some extent. In particular, when the parts of the fibrous web diverge after hitting the baffle, a concave side of the baffle may parallelize the parts of the fibrous web. The parts of the fibrous web then run parallel again in the outlet opening, which improves the quality of the emerging sliver.

If the at least one straight side of the impact element has an angle to the z-direction between 25 ° and 70 °, in particular between 35 ° and 60 °, preferably 45 °, this entails additional advantages. By means of the angle, the movement of the parts of the nonwoven fabric from the x-direction in the z-direction, in particular in the output port, are redirected. According to the principle of incident angle equal to the angle of reflection, the parts of the nonwoven fabric can be deflected at the at least one straight side. Parts of the nonwoven fabric that do not move exclusively in the x direction can also be redirected in the z direction. For example, if parts of the fibrous web move away from the exit opening after hitting the baffle, a higher angle of the face of the baffle may redirect the portions of the fibrous web in the z-direction, particularly the exit orifice. A lesser angle may be used when the portions of the fibrous web flow at a shallow angle toward the exit port. A straight side which is at 45 ° to the z-direction can be used when the parts of the fibrous web have been diverted exactly in the x-direction from the guide surface. By means of the angle, the sliver is diverted in the z direction, resulting in parallel fibers of the exiting sliver. This increases the quality of the sliver.

Furthermore, it is advantageous if the guide element is designed as a flow element in order to introduce an air flow into the fleece funnel in order to limit the movement of the fiber fleece in the x direction. By means of an air flow, the movement of the parts of the non-woven fabric can be gently limited and redirected into the outlet opening, in particular in the z-direction. In addition, the strength of the introduced air flow, in particular the air velocity and / or the air flow density, can also be varied. For example, at higher production speeds, such as when the fibrous web is introduced into the fleece funnel at a higher velocity, a greater flow of air may be introduced by means of the flow member to further confidently confine and / or redirect the x-direction moving parts of the fibrous web. The flow element may be formed as a nozzle which is connected to a controllable air pressure source. The air flow leaves the flow element and is preferably directed in the direction of the outlet opening, so that the air flow exits through the outlet opening with the sliver again. By means of the flow element, the exit of the sliver can also be supported by the outlet opening.

An advantageous development of the invention is when the guide element has a roof element in order to guide the fiber fleece entering the fleece funnel over the guide element in the region of the guide element. With the roof element, the nonwoven fabric is gently guided over the guide element. The fiber fleece is thus not divided by the guide element itself and / or hindered in its direct movement, in particular such movements that lead directly into the exit openings. The roof element can also limit the proportionate movement of the fiber web in the y-direction.

Likewise, it is advantageous if the guide element is designed as a pivoting element which limits the proportionate movement of the fiber web in the y-direction. In particular, the pivoting element may be arranged in addition to the baffle element in the nonwoven funnel, so that the nonwoven funnel has two guide elements. The pivoting element can be pivoted about a pivot axis, whereby its orientation can be changed. The pivot axis may extend in a region between the input side and the baffle element. The pivot element may be pivoted while the nonwoven fabric is being compacted by the nonwoven strainer so that the pivot element can be pivoted into the nonwoven fabric and / or swung away. Thus, the proportionate in y-direction movement of the nonwoven fabric by means of the pivoting element can be limited stronger or weaker. This can be advantageous, for example, if the speed of the fiber web entering the fleece funnel increases or decreases. In addition, the pivoting member may be pivoted away from the fibrous web, for example when the fibrous web has reached its terminal velocity with which it flows through the web straightener. In particular, when the loop has expanded into free space as described above, the pivot member can be pivoted away. The loop remains stable itself. This reduces a braking effect of the pivoting element on the nonwoven fabric.

It is also advantageous if the pivoting element is pivotable about an axis of rotation in the x direction, about a pivot axis extending in the y direction and / or about a pivot axis extending in the z direction. This can be addressed on an orientation of the incoming nonwoven fabric. For example, with a pivot axis oriented in the x direction, the pivot member may be pivoted into or away from the fibrous web. In particular, the pivoting element can be pivoted such that it has no influence on the nonwoven fabric, for example when the pivoting element is oriented parallel to the nonwoven fabric.

The pivoting element can be arranged for example with a ball joint on the pivot axis, so that with the ball joint, the pivoting element is pivotable about at least two pivot axes. This can be better addressed to the orientation of the nonwoven fabric with the pivoting element.

An advantageous development of the invention is when the pivoting element in the x-direction, in the y-direction and / or in the z-direction is displaceable. In particular, the pivot axis is thereby displaced, so that not only the orientation of the pivot element but also the position of the pivot element can be changed. For example, if the nonwoven fabric enters the nonwoven funnel at different times at different locations, the pivoting element can be repositioned corresponding to the nonwoven fabric. In addition, the pivoting element can be moved completely out of the fleece funnel.

The pivoting element can be pulled out of the fleece funnel in a y-direction. In particular, the pivoting member is pulled away from the loop described above away from the fleece funnel. If the fleece funnel has a cover, the pivoting element can also be pulled out of the fleece funnel over the cover. This is advantageous when the final speed of the incoming nonwoven fabric reaches and the nonwoven fabric has formed a stable loop in the nonwoven funnel.

Furthermore, it is advantageous if the roof element is designed as a pivoting element. This simplifies the construction of the fleece funnel. The roof element in this embodiment could first limit the nonwoven fabric in the y direction in such a way that the loop is formed. If the loop is then formed, it could be pivoted so that the roof element guides the fibrous web over the baffle, for example.

The pivoting element can be pivoted about the pivot axis manually or by means of a drive, for example by means of a servomotor or a hydraulic and / or pneumatic device.

Additionally or alternatively, the pivoting element can also be fixable, so that it is not pivotable during operation of the fleece straightener.

It is also advantageous if the pivoting element has the greatest width at its center and is made narrower towards the sides. As a result, the effect limiting in the y direction is intensified on central parts of the fiber fleece. The looping for the middle parts of the nonwoven fabric can thus be strengthened.

Advantageously, the pivoting element has an extension in a central region in the x-direction. The extension is preferably arranged in a region above the exit opening through the central arrangement. The extension has a distance to the exit opening, which depends on the arrangement in the z-direction of the pivot member and a length of the extension. By means of the extension, in particular the central parts of the fibrous web are limited in a movement in the y-direction. Such parts are prevented in particular by the extension of it in the y-direction on the guide element, preferably on the baffle element, to push. Furthermore, with the extension, a loop can be imposed on the middle parts of the fiber fleece, which loop is formed in the y-direction and leads away from the guide element. This prevents kinking of these parts of the fibrous web over the exit opening.

In addition, the pivoting member and / or the extension equalize the path that the various parts of the fibrous web must travel back into the exit opening. Parts of the fiber fleece, which flow directly into the outlet opening, have to travel a smaller distance overall than parts of the fiber fleece, for example, first encounter the guide surfaces. By looping this path difference is compensated. This leads to a better sliver quality. By means of the extension, this effect can also be achieved. In particular, the middle parts of the fibrous web must make a detour over the extension. This detour compensates for the path difference.

Additionally or alternatively, the extension can also be arranged on the roof element. Such a design can save material and manufacturing costs.

The extension can be formed integrally with the pivoting element and / or the roof element. This simplifies the manufacturing process.

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

1 FIG. 2 a sectional view of a fleece straightener with a guide element designed as a baffle element, FIG.

2 a sectional view of a fleece with the baffle element, which has two converging at an angle sides,

3 3 a sectional view of a fleece straightener with the impact element, wherein the two sides are concave,

4 a plan view of a fleece funnel with the baffle element,

5 a side sectional view of a fleece funnel with the baffle element,

6 a sectional view of a fleece straightener with the baffle element and a roof element,

7 a sectional view of a fleece with the baffle element and two gradations,

8th a sectional view of a web straightener with a nozzle as a flow element,

9 a side sectional view of a fleece straightener with a baffle element and a pivoting element,

10 a further sectional side view of a fleece straightener with a baffle element and a pivoting element,

11 a plan view of a fleece funnel with a pivoting element,

12 a sectional view of a fleece straightener with a baffle element and a pivoting element, and

13 a sectional view of a fleece straightener with a baffle element, a pivoting element and an extension arranged thereon.

1 shows a sectional view of a fleece judge 1 with an elongated in the x-direction input side 2 , A non-woven fabric, not shown here, passes through the entrance side 2 in the fleece funnel 1 one. From the entrance side 2 is in the z-direction an output side 3 spaced. In the exit side 3 is an exit port 4 formed, through which the fiber web compressed to a sliver of nonwoven fabric 1 exit. The exit opening 4 is preferably formed with a round cross-section. In this embodiment, between the input side 2 and the output side 3 two fins 5a . 5b arranged, which is the actual funnel function of the web guide 1 form. A nonwoven fabric spread in the x direction passes through the entrance side 2 in the fleece funnel 1 one. At least the edge regions of the fiber fleece meet the guide surfaces 5a . 5b and from there towards the exit opening 4 redirected, where there is the fleece funnel 1 as sliver leaves.

Between the entrance side 2 and the exit port 4 is arranged a guide element. In this embodiment, the guide element is a baffle element 6 educated. The impact element 6 is further between the two fins 5a . 5b arranged. In addition, the baffle element has 6 in this embodiment two pages 7a . 7b on top of the fins 5a . 5b are opposite. The impact element 6 is preferably on a cover 8th arranged the fleece funnel 1 on at least one side in the y-direction (cf. 4 ) completes.

As already described above, the nonwoven fabric in this embodiment is at the guide surfaces 5a . 5b in the direction of the exit opening 4 diverted. At least parts, in particular edge regions, of the nonwoven fabric which is spread out in the x direction and at first moves only in the z direction are obtained by means of the impact on the guide surfaces 5a . 5b a movement in the x-direction. Parts on the baffle 5a hit, get a movement in the x-direction to the exit opening 4 and parts of the fibrous web which are on the guide surface 5b hit, get a movement against the x-direction to the exit opening 4 , The impact element 6 limits the proportionate in the x-direction movement of the parts of the non-woven fabric, that of the respective guide surfaces 5a . 5b come. The parts of the fiber fleece bounce off the guide surface 5a Preferably come to the side 7a of the baffle element 6 , Parts of the non-woven fabric from the guide surface 5b come, however, preferably bounce on the side 7b of the baffle element 6 , In particular, by means of the impact element 6 prevents the parts of the fibrous web from coming off the baffle 5a come face-to-face with the parts of the non-woven fabric coming from the baffle 5b come.

Such collision would lead to a chaotic or unwanted and disordered arrangement of the individual fibers in the emerging sliver. The fiber quality in such a sliver would be lower, which would be with a guiding element in the fleece funnel 1 is prevented.

In this embodiment, the baffle element 6 an x-dimension equal to the diameter of the exit opening 4 is. The impact element 6 however, it may also be narrower or wider, in particular from 0.25 times to 4 times the x-dimension of the exit opening 4 ,

In addition, the baffle element 6 also in z-direction to the input side 2 or be formed beyond. Also, a z-extension of the impact element 6 conceivable, that is 0.1 times the z-dimension of the web straightener 1 equivalent.

Another embodiment is in 2 shown. From here, the same features that have the same or at least a similar effect are not explained in addition. However, such features continue to receive the same reference numerals as in the 1 ,

The guide element is a baffle element 6 educated. The page 7b is at an angle α of the guide surface 5b inclined. The page 7a has advantageously the same angle α to the z-direction, but may also be different. The page 7a is the guide surface 5a inclined. The angle α is between 25 ° and 70 °, in particular between 35 ° and 60 °, preferably at 45 °.

The angle α is advantageous in that, for example, parts of the non-woven fabric, the of the guide surface 5a come to have a proportional movement from the exit port 4 leads away. Especially from the flat areas of the fins 5a . 5b leading to the exit opening 4 are adjacent, parts of the non-woven fabric, from the direction of the input side 2 flow in, again in the direction of the entrance side 2 bounce. In general, however, the parts of the nonwoven fabric have a superposition of a movement in the x-direction and in the z-direction. The parts of the fins 5a . 5b can be diverted, therefore obliquely over the exit opening 4 and move away from it. Then meet such parts of the nonwoven fabric on the respective pages 7a . 7b of impactor 6 having the angle α. The pages 7a . 7b limit on the one hand the movement of the parts of the fiber fleece and direct this to the other in the direction of the exit opening 4 around.

An angle α of 45 ° can be provided, for example, if the parts of the non-woven fabric, that of the guide surfaces 5a . 5b come, move in the x-direction. These then become 90 ° from the x-direction in the z-direction, and in particular into the exit opening 4 , redirected.

3 shows a further alternative embodiment of the fleece judge 1 , The pages 7a . 7b of the baffle element 6 are concave. At the concave sides 7a . 7b Can the from the fins 5a . 5b be redirected parts of the nonwoven fabric.

Furthermore, also parts of the fiber fleece on the sides 7a . 7b be deflected, which is not exclusively parallel to the fins 5a . 5b come. For example, it may happen that parts of the nonwoven fabric are from the fins 5a . 5b were diverted, diverge. The concave sides 7a . 7b thus have a focusing effect on the parts of the nonwoven fabric. This in particular a shrinkage of the nonwoven fabric is supported in total, which increases the quality of the sliver.

In 4 is a plan view of a fleece judge 1 with a baffle element 6 shown. The fleece funnel 1 is on at least one side in the y-direction with a cover 8th closed. At the cover 8th is advantageously arranged the guide element. In this embodiment, the baffle element 6 on the cover 8th arranged. The impact element 6 is in the y-direction from the exit port 4 staggered. The pages 7a . 7b of the baffle element 6 are concave, but may also be straight. The concave shape of the sides 7a . 7b advantageously promotes the introduction of the baffles 5a . 5b coming parts of the fiber fleece. In addition, the impact element limits 6 a movement of the parts of the fibrous web in the x direction. The parts of the nonwoven fabric from a baffle 5a . 5b come, by means of the impact element 6 prevented at the exit port 4 over into the respective other area of the guide surface 5a . 5b to pour over. Especially on the sides 7a . 7b bounce off the parts of the fiber fleece and be by means of the sides 7a . 7b in the exit opening 4 diverted.

In this embodiment, the baffle closes 6 directly to the exit opening 4 at. It is also possible, however, that the baffle element 6 with an area above the exit opening 4 stands. It is also possible that the baffle element 6 from the exit opening 4 is spaced in the y-direction, ie in the plan view between the outlet opening 4 and the baffle element 6 has a gap.

A side sectional drawing of a fleece judge 1 with a baffle element 6 is in the embodiment in 5 shown. The fleece funnel 1 is in the y-direction on at least one side with a cover 8th closed. The guide surface 5a is trapezoidal, in particular in the z-direction to the input side 2 rejuvenating, trained.

At the cover 8th is the baffle element 6 arranged. In this sectional drawing is the baffle element 6 triangular shaped. The impact element 6 widens in the direction of the exit opening 4 , Thus, the baffle element 6 immediately before the exit opening 4 the biggest limiting effect on.

The impact element 6 closes in this embodiment to the output port 4 at. As already in 4 described, it is also possible that the baffle element 6 with an area over the exit opening 4 enough. In addition, the baffle element 6 also from the exit opening 4 be spaced, so that a gap between these two is formed.

In 6 is another alternative embodiment of a fleece judge 1 with a baffle element 6 trained guide shown. This shows the baffle element 6 a roof element 9 on, over the pages 7a . 7b protrudes and inclined to the xy plane. About the roof element 9 becomes one from the direction of the input side 2 inflowing fiber fleece over the baffle element 6 directed. This prevents in particular that the baffle element 6 even a direct (especially such parts of the fiber fleece, not from the fins 5a . 5b to be diverted) infiltrated by parts of the nonwoven fabric. This increases the quality of the emerging sliver.

In the 7 is an additional advantageous embodiment of a fleece judge 1 with a baffle element 6 trained guide shown. The impact element 6 indicates at the exit opening 4 opposite end a bevel 10 on, which is inclined to the xy plane.

Additionally or alternatively, the baffles 5a . 5b one graduation each 11a . 11b exhibit. After an impact of the parts of the fiber fleece on the fins 5a . 5b these parts slip over the respective gradation 11a . 11b , Thus, the nonwoven fabric becomes more homogeneous in the direction of the exit opening 4 directed.

In the 8th is another embodiment of a fleece judge 1 with a flow element as a guide element, which serves as a nozzle 12 is formed, shown. By means of the nozzle 12 and a controllable air pressure source, not shown, an air flow in the fleece funnel 1 be introduced. On the one hand, such an air flow limits movement of parts of the nonwoven fabric in the x direction. The parts of the nonwoven fabric from the baffles 5a . 5b come, meet in the x-area of the nozzle 12 on an air jet formed by the air flow. This limits the movement of the parts of the fiber fleece. On the other hand, the jet of air directs the fiber fleece into the exit opening 4 ,

In addition, the flow element, in particular the nozzle 12 to have a roof element, as in 6 described the non-woven fabric over the nozzle 12 to lead away.

In the 9 is a side sectional view of a fleece judge 1 with a baffle element 6 and a pivoting element 13 shown. The guide surface 5a is conically tapered in the z-direction. Through the entrance side 2 a fiber fleece enters the fleece funnel 1 on and at the exit side 3 out again. The fiber web compressed into a sliver passes through the exit port 4 again from the fleece funnel 1 out. Between the entrance side 2 and the exit port 4 is the baffle element 6 arranged. This is against the exit opening 4 arranged offset in the y direction. Between the baffle element 6 and the input side 2 is further the pivoting element 13 arranged. This is at the pivot axis 14 rotatably arranged. The pivoting element 13 can be pivoted in the pivoting direction xSR. The pivoting direction xSR is arranged in a yz-plane, is thus perpendicular to the x-direction. The pivoting direction xSR is achieved by pivoting the pivoting element 13 around the pivot axis running in the x-direction 14 educated. When the swivel element 13 for example, from the cover 8th is pivoted away, the incoming nonwoven fabric is more affected. In particular, the nonwoven fabric becomes after entry from the cover 8th guided away. The nonwoven introduces a loop from the cover 8th is directed away, and then flows into the output port 4 , Before the fiber fleece in the exit opening 4 enters, the nonwoven fabric in the manner described above with the baffle element 6 interact. By means of this embodiment, a movement of parts of the fiber web is first in the y direction on the pivot member 13 and then in the x direction on the baffle element 6 limited.

Alternatively, the pivoting element 13 also be designed to be longer than shown here, so that it is in the position shown here beyond the exit opening 4 and over the baffle element 6 enough. This may enhance the y-direction limiting effect.

In addition, the distance between baffle element 6 and the pivot axis 14 be reduced and / or enlarged. For example, the pivot axis could 14 directly above the baffle element 6 be arranged. The pivot axis 14 can also be moved in z-direction on the cover.

Additionally or alternatively, the pivoting element could 13 at the in y-direction to the cover 8th spaced front of the baffle element 6 be arranged.

Furthermore, the pivot axis could 14 also completely in the cover 8th be arranged. This leads to a pivoting back of the pivoting element 13 when the pivoting element 13 so that it is arranged parallel to the z-direction, is arranged plan in the cover. The pivoting element 13 forms a part of the cover, so to speak 8th , This has the advantage that the pivoting element 13 in such a pivoted position has no influence on the incoming nonwoven fabric. In particular, when the limiting effect in the y direction of the pivoting element 13 is no longer needed, this can be swung back, where it is then arranged plan in the cover.

In 10 is another embodiment of a fleece judge 1 with a pivoting element 13 shown. An explanation of equivalent features is omitted for the sake of simplicity. In this embodiment, the pivot axis 14 formed running in the y-direction. The pivoting element 13 is thus pivotable in the pivoting direction ySR.

In 11 is a plan view of a fleece funnel 1 with a pivoting element 13 shown. Again, it should be compared to the other figures only to the essential differences for the sake of simplicity. In this embodiment, the pivot axis 14 arranged in the z-direction running. Thus, the pivoting element 13 pivotable about a pivoting direction zSR. The pivoting element 13 swings in an xy plane. This has the advantage that when not parallel to the cover 8th entering fiber fleece in the fleece funnel 1 , the pivoting element 13 can be adapted to such a sloping incoming nonwoven fabric. The fleece funnel 1 next to it has a guide element, not shown here. The guide element is as in the other figures, for example as a baffle element 6 and / or as a nozzle 12 educated.

In 12 is a sectional view of a fleece judge 1 with a baffle element 6 and a pivoting element 13 shown. The 12 shows all compared to the 7 same or at least similar acting features that will not be explained again for the sake of simplicity. It will be discussed here only on the essential differences.

In the area of the entrance side 2 is a pivoting element 13 with the pivot axis 14 arranged. The pivoting element 13 is between the input side 2 and the baffle element 6 arranged. The side of the pivoting element 15 is convex, but may, for example, additionally or alternatively be straight and / or concave.

Furthermore, the pivoting element 13 be formed in its x-extension wider or narrower than shown here. Also, the distance between the side of the pivoting element 15 and the pivot axis 14 be formed larger or smaller. The pivoting element 13 will be longer.

The pivot axis 14 may also be shifted in the z-direction. For example, the pivot axis 14 continue in the direction of the impact element 6 be postponed. If the pivot axis 14 and thus also the pivoting element 13 directly to the baffle element 6 connect, the pivot element acts 13 similar to a roof element 9 (see. 6 ). Then, however, the pivoting element 13 only upwards, from the baffle element 6 away, swiveling.

By means of the pivoting element 13 this will be in the fleece funnel 1 entering fiber web limited in its movement in the y direction. In particular, parts in the middle of the nonwoven fabric are on the pivoting element 13 diverted and limited in motion in the y direction. Parts of the fibrous web at the edge are first on the pivoting element 13 distracted and limited in their movement and then at the fins 5a . 5b in the direction of the exit opening 4 diverted. If the fibrous web in its x-extension wider than the pivoting element 13 is, has the pivoting element 13 only influence on a section of the fiber fleece. In particular, the parts of the fiber fleece at the edge meet only on the fins 5a . 5b and become in the direction of the impact element 6 diverted, with these on the baffle element 6 can be limited in their movement in the x direction. The nonwoven fabric thus has areas that only by means of the pivoting element 13 in the y direction, by means of the impact element 6 in the x-direction or by means of both elements 6 . 13 are limited in x and y directions.

In 13 is a sectional view of a fleece judge 1 with a baffle element 6 , a pivoting element 13 and an extension arranged thereon 16 shown. Here again, only the essential differences from the preceding embodiments will be explained for the sake of simplicity.

The pivoting element 13 indicates the extension in an area in the middle of its x-dimension 16 on. This lengthens the pivoting element 13 towards the middle. In this view, the z-dimension becomes the center of the panning element 13 through the extension 16 increased. The extension 16 preferably works path compensating. The parts of the sliver passing over the fins 5a . 5b To flow into the exit port, must travel a longer distance than the parts of the sliver, which are arranged in the middle and flow directly into the outlet opening. The parts of the fibrous web in the middle always flow first through the exit opening 4 , Depending on the speed of the fibrous web and the extent of the web straightener, the parts of the fibrous web flow laterally into the exit opening at the edge 4 , This leads to a delay of the individual fibers in the nonwoven fabric with each other. By means of the extension 16 the middle parts of the fiber fleece are guided in a detour. In particular, a loop is formed by the pivoting element 13 away, out. This detour, especially the loop, compensates for the path difference between the different parts of the fiber fleece. The different parts of the fiber fleece thus flow simultaneously into the outlet opening 4 , The sliver quality is thereby increased.

By means of the shape of the extension 16 the distance traveled by the different parts of the nonwoven fabric can be changed.

Through the pivot axis 14 is the pivoting element 13 with the extension 16 pivotable. Thus, for example, during a running operation of a spinning machine, the sliver can be influenced. For example, during operation, the path that the parts of the sliver about the pivoting element 13 must be changed in order to achieve an optimal quality adjustment of the emerging sliver.

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

 fleece funnel

2

 input side

3

 output side

4

 output port

5

 baffle

6

 baffle

7

 Side of the baffle element

8th

 cover

9

 roof element

10

bevel

11

gradation

12

jet

13

pivoting element

14

swivel axis

15

Side of the pivoting element

16

extension

α

 angle

 XSR

 pan direction

 YSR

 pan direction

 ZSR

 pan 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

• DE 10230433 A1 [0002]

Claims (17)

Nonwoven funnel for compacting a non-woven fabric, in particular on a track, carding machine or combing machine, with an input side elongated in the x-direction (US Pat. 2 ), at which the spread fiber fleece in the fleece funnel ( 1 ) and one in z-direction to the input side ( 2 ) spaced output side ( 3 ), on which the nonwoven fabric as a sliver from the fleece funnel ( 1 ), with an exit opening ( 4 ), which on the output side ( 3 ) is arranged and with at least one between input side ( 2 ) and output side ( 3 ) arranged guide surface ( 5a . 5b ) for the non-woven fabric, in order to place it in the fleece funnel ( 1 ) inflowing fiber fleece in the direction of the exit opening ( 4 ), characterized in that in an area between the input side ( 2 ) and exit opening ( 4 ) at least one guiding element ( 6 . 12 ) is arranged, which limits a in the x-direction and / or a proportionate in y-direction movement of the fibrous web. Nonwoven funnel according to the preceding claim, characterized in that the guide element ( 6 . 12 ) in the y-direction, which is oriented orthogonal to the x and z direction, offset from the exit opening ( 4 ) is arranged. Nonwoven funnel according to one or more of the preceding claims, characterized in that the guide element ( 6 . 12 ) as a baffle element ( 6 ) is formed, the at least one of the at least one guide surface ( 5a . 5b ) facing side ( 7a . 7b ), at which at least parts of the non-woven fabric bounce off. Nonwoven funnel according to one or more of the preceding claims, characterized in that the baffle element ( 6 ) is formed prism-shaped. Nonwoven funnel according to one or more of the preceding claims, characterized in that the baffle element ( 6 ) has a z-direction tapered shape. Nonwoven funnel according to one or more of the preceding claims, characterized in that the baffle element ( 6 ) in its x-dimension, in particular to the exit opening ( 4 ), is tapered. Nonwoven funnel according to one or more of the preceding claims, characterized in that the baffle element ( 6 ) in its y-dimension, in particular from the exit opening ( 4 ) away, is tapered. Nonwoven funnel according to one or more of the preceding claims, characterized in that the at least one side ( 7a . 7b ) of the impact element ( 6 ), bounce off at the parts of the nonwoven fabric, is straight and / or concave. Nonwoven funnel according to one or more of the preceding claims, characterized in that the at least one side ( 7a . 7b ) of the impact element ( 6 ) has an angle (α) to the z-direction between 25 ° and 70 °, in particular between 35 ° and 60 °, preferably 45 °. Nonwoven funnel according to one or more of the preceding claims, characterized in that the guide element ( 6 . 12 ) as a flow element, preferably as a nozzle ( 12 ), is designed to allow air flow into the fleece funnel ( 1 ) in order to limit the proportion of movement of the fiber web in the x-direction. Nonwoven funnel according to one or more of the preceding claims, characterized in that the guide element ( 6 . 12 ) a roof element ( 9 ) in order in the region of the guide element ( 6 . 12 ) in the fleece funnel ( 1 ) entering fiber fleece over the guide element ( 6 . 12 ). Nonwoven funnel according to one or more of the preceding claims, characterized in that the guide element as a pivoting element ( 13 ) is formed, which limits the proportionate movement of the fiber web in the y direction and that the pivoting element ( 13 ) on a pivot axis ( 14 ) is pivotable. Nonwoven funnel according to one or more of the preceding claims, characterized in that the pivoting element ( 13 ) about an axis of rotation in the x-direction, in the y-direction and / or in the z-direction extending pivot axis ( 14 ) is pivotable. Nonwoven funnel according to one or more of the preceding claims, characterized in that the pivoting element ( 13 ), in particular the pivot axis ( 14 ), in the x-direction, in the y-direction and / or in the z-direction is displaceable. Nonwoven funnel according to one or more of the preceding claims, characterized in that the roof element ( 9 ) as a pivoting element ( 13 ) is trained. Nonwoven funnel according to one or more of the preceding claims, characterized in that the pivoting element ( 13 ) has in its center the greatest width and is narrowing towards the sides. Fleece straightener according to one or more of the preceding claims, characterized in that in a central region of the x-direction Swivel element ( 13 ) and / or the roof element ( 9 ) An extension is arranged.

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