JP2003003339A - Rotary table for storing sliver, especially in drawing frame, carding machine, etc. - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a frictional resistance between a sliver and a sliver passage. SOLUTION: This rotary table for storing a sliver, especially in a drawing frame and a carding machine is equipped with an entrance for the sliver 12a and exit 12b, in which the entrance is arranged in the vicinity of a rotating axis line or on the same axis line and the exit is arranged remotely against the entrance in its radial direction and axis direction, and the spatially bent sliver passage 12. Since the sliver 9 receives a drawing draft in the rotary table for storing the sliver, especially in a drawing frame, a carding machine, etc., there is a relative movement between the transferring sliver and the inner wall 12c of the sliver passage 12 and a frictional resistance acts on the sliver through the inner wall. In order to enable the improvement of sliver guidance and sliver quality, the frictional resistance is reduced at least partially by changing the interaction and/or spatial arrangement between the sliver 9 and the inner wall 12c of the sliver passage 12c.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention comprises a sliver inlet and outlet having an inlet disposed near or coaxial with a rotation axis and an outlet disposed radially and axially away from the inlet. , Having a spatially bent sliver passage, a tension draft acts on the moving sliver through the sliver, and there is relative movement between the moving sliver and the inner wall of the sliver passage, and the inner wall of the sliver passage Relates to a rotary table for a sliver storage device such as a kneading machine and a carding machine, which acts on friction resistance.

[0002]

In operation, the sliver in the sliver passage carries out several movements and is subjected to several forces. Between the take-off roller and the self-moving container, the sliver undergoes a known delivery draft, i.e. a traction force is applied, which causes the sliver to move from the inlet to the outlet. Due to the fact that the outlet is arranged axially distant from the inlet, the rotational movement exerts an additional centrifugal force outwardly and laterally on the sliver, which is unexpectedly unwarranted by the "bulge". May cause force. The outwardly acting centrifugal force is reduced by reducing the distance of the curved sliver passage to the axis of rotation, i.e. the "bulge" of the inner wall acting as a reaction force on the sliver is reduced. The reaction force causes a high friction of the fibrous material with the inner wall, which impairs the moving speed of the sliver and also eliminates unduly drafts that cause friction.

For delivery speeds up to 1000 m / min, rotary tables with curved sliver passages made of polished special steel have been proposed. However, it has been proved that this method cannot continuously increase the moving speed of the sliver exceeding 1000 m / min. Especially in delicate sliver machines, large frictional forces on the inner wall lead to undesired and unfavorable drafts.

[0004]

On the other hand, the present invention has the object of providing a rotary table of the initially mentioned technique which avoids the abovementioned disadvantages and in particular enables sliver guidance and improvement of the sliver quality. It is based on

[0005]

The solution to this problem is achieved by the structure of the characterizing portion of claim 1.

The procedure according to the invention allows for different movements of the sliver in the interior space of the sliver passage and the effect of different forces on the sliver. The forces acting do not occur at the same magnitude everywhere. To that end, by changing the interaction and / or the arrangement between the sliver and the inner wall, the undesired or disturbing forces can be dealt with partially and individually. In this way, a substantial improvement in sliver guidance and sliver quality is achieved and, in particular, a considerable increase in sliver travel speed of more than 1000 m / min in the mixer can be achieved. To the same extent, the improved sliver guidance according to the invention enables an improved sliver quality, especially in carding machines, under sliver travel speeds below 1000 m / min.
The sliver is essentially homogeneous, i.e. uniform with respect to the draft in the various zones. The partial draft in the sliver passage and its action on the section or region of the sliver are uniform, and the tensile draft is improved as a whole.

Claims 2 to 22 contain advantageous further configurations of the invention.

[0008]

The invention is explained in more detail below on the basis of an embodiment shown in the drawing.

The side view according to FIG. 1 shows (partially) an introduction area 1, a measurement area 2, a draft area (draft roller) 3 and a sliver container storage 4 of a kneading machine, for example a Trützler-type kneading machine HSR. There is. In the introduction area 1, a sliver container (round container) 5 of a kneading machine having two container rows is arranged below the sliver introduction table 6 (creel),
The supply sliver 7 is drawn in via the introduction roller 8 and then introduced into the draft roller 3. After passing through the draft area 3, the stretched sliver 9 reaches the turntable 10 of the sliver container storage 4 and is delivered in a ring into the outlet container 11. A sliver passage 12, for example, a curved pipe, is arranged in the turntable 10 through which the sliver 9 moves. The letter A indicates the operating direction of the kneading machine. Reference numerals 17a and 17b
Shows a calendar roller.

FIG. 2 shows a supply roller 21, a supply table 22, a take-in roll 23, a cylinder 24, a doffer 25, a take-up roller 26, squeeze rollers 27 and 28, a fleece guide 29, a trumpet 30, and a delivery roller 3.
A rotary flat 33 having a flat bar 34,
1 shows a carding machine provided with calender rollers 17a and 17b covers, a sliver container 11 and a sliver container storage 20. For example, a high-performance carding machine of the Trützler type is shown. The direction of rotation of the roller is indicated by the curved arrow. The letter B indicates the operating direction of the carding machine. There is a housing above the cover plate of the sliver container storage 20 and inside there is a swiveling turntable 10. Sliver container 11
Is moved by a drive (not shown) while the sliver 13 is being filled through the turntable 10. A sliver passage 12, for example, a curved pipe is arranged in the rotary table 10, and the sliver 13 moves through the sliver passage 12.

According to FIG. 3, the sliver passage 12 is spatially bent and has an inlet 12a and an outlet 12b for the sliver 9 (see FIG. 4). The inlet 12a is arranged coaxially with the axis of rotation 16 and the outlet 12b is arranged at a radial distance a and an axial distance b with respect to the inlet 12a. The turntable 10 is arranged in a fixed-position panel 14. The rotary table 10 has a sliver guide passage 12, for example, a curved pipe, between the sliver inlet opening 12a and the sliver outlet opening 12b. The sliver outlet opening 12b in the lower rotary head plate 15 has a substantially elliptical shape. The sliver 9 moves in the direction of the arrow in the sliver passage 12 and enters the sliver container 11 through the sliver outlet opening 12b (see FIG. 1). Reference numerals 15a, 15
A ball bearing is indicated by b.

The sliver 9 is subjected to a light tension draft in the sliver passage 12, that is, a traction force Z acts. During passage, the sliver 9 follows the bend in the sliver passage 12. Due to this bend and traction, the sliver 9
Is the inner wall 12c of the sliver passage 12 in the regions x and y.
Then, the pressing force, that is, the frictional forces P ₁ and P ₂ are applied to the inner wall 12 except for the remaining positions. Relative motion occurs between the traveling sliver 9 and the inner wall 12c.

The frictional resistance between the sliver 9 and the inner wall 12c is reduced according to the invention by the interaction between the sliver 9 and the inner wall 12c of the sliver passage 12 and / or by a change in the spatial arrangement. The "critical" regions x, y of the inner wall 12c have an important meaning here. Therefore, the friction between the sliver 9 and the regions x, y of the inner wall 12c can be reduced by decreasing the friction coefficient μ, by decreasing the friction angle α, and / or by increasing the radius of curvature r. Further, the tension draft determined by the calender rollers 17a and 17b and the weight of the container 11 can be changed (tensile force Z). This measure reduces the pressing forces P ₁ , P ₂ individually or in combination. This also applies to the sliver 13 shown in FIG.

The sliver 9 is sent out by rotating the sliver 9 and 13 produced by the sliver forming machine in a sliver container 11 in an annular shape.
Performed by 0. The annular formation is carried out by a combination of two rotary movements, a fast movement carried out by the turntable 10 and a slow movement carried out by the sliver container 11 (in the case of a rectangular container the second movement is a translation). ). In the sliver storage process, the sliver 9 and 13 in the sliver passage (tube) 12 are subjected to various forces. The gravitational force, the centrifugal force, the biasing force due to the acting tensile force, and the frictional force between the sliver 9 and 13 and the pipe inner wall 12c that act in a direction opposing the moving direction of the sliver 9 and 13 and thereby interfere with the sliver storage process. Works. The tension draft is measured to obtain the correct delivery situation, so that the sliver in the sliver passage 12 is always under some tension. In this way, the sliver is always leaning against the small radius portion of each curved portion that is bent to a middle height in the curved region of the sliver passage 12. The above-mentioned frictional force is substantially in this contact area x, y
It is caused by the interaction between the sliver and the tube. The above-mentioned adverse effects on the operating conditions of the machine and the sliver quality are caused, inter alia, by this friction between the sliver 9 and the inner wall 12c of the sliver passage 12 which guides it.

In order to improve the sliver guide in the sliver passage 12 of the rotary table 10, the following steps are carried out individually or in combination.

A sliver passage (tube) 1 made from a fibrous material and a material that is inspected or has low friction in each segment.
The degree of friction with the inner surface 12c of No. 2 is reduced. In this way, for example, the tension is reduced, and undue drafts are prevented thereby.

The geometrical shape of the sliver guide organ is such that the unraveling of the fiber material is the sliver passage (sliver guide organ) 12
Modified to be prevented by the peripheral surface.

The geometrical shape of the sliver guide organ 12 is
In particular, it is widened at the inlet 12a. This minimizes the relaxation phenomenon due to the sliver passages (sliver guide organs) 12 of the sliver 9, 13 under the influence of tension.

External force is applied to the slivers 9 and 13 (for example, by generation of a magnetic field or an electric field). This reduces, for example, the friction between the fibers and the fiber guiding surface 12c.

The variations in sliver load caused by sliver storage are regulated by controlled factors such as vessels.

The sliver guide distance is reduced by the integrated structure of the rotary table and the sliver guide passage (guide organ).

Sliver passage (sliver guide organ) 12
Have an alternative to the round implementation shape (eg, elliptical).

The measures for reducing the comparative relaxation in the sliver passages (sliver guide organs) are applied in kneaders, carders and combs.

[Brief description of drawings]

FIG. 1 is a side view showing a kneading machine equipped with a rotary table according to the present invention.

FIG. 2 is a side view showing a carding machine provided with a rotary table according to the present invention.

FIG. 3 is a sectional view showing a rotary table having a sliver passage according to FIGS. 1 and 2.

FIG. 4 is a cross-sectional view showing a side surface of a sliver passage together with a sliver.

FIG. 5 is a plan view showing a sliver passage.

[Explanation of symbols]

9 ... Sliver 10 ... rotary table 11 ... Container 12 ... Sliver passage 13 ... Sliver

Continued front page    (72) Inventor Hokuri Kheriff             Germany, Day-85057 Ingo             Lestadt, Herkommerstraße             Three (72) Inventor Burghard Bruchhorst             Day 52223 Stol, Federal Republic of Germany             Berg, Roland Strasse 37 F-term (reference) 4L056 BA11 BE01 CA02 CA12 CA29                       CA42 CA70 DA48

Claims (22)

[Claims] 1. A sliver inlet and outlet, wherein the inlet is disposed near or coaxial with the axis of rotation and the outlet is radially and axially spaced from the inlet, and is spatially bent. The sliver is under tension draft, and there is relative movement between the moving sliver and the inner wall of the sliver passage, through which friction resistance acts on the sliver. A rotary table for a sliver storage device such as a kneading machine or a carding machine, in which the interaction and / or the spatial arrangement between the sliver (9, 13) and the inner wall (12c) of the sliver passage (12) are provided. A rotary table, characterized in that the friction resistance is at least partly reduced by a modification. 2. The rotary table according to claim 1, wherein the frictional resistance can be partially reduced adjacent to the inner wall (12c). 3. The rotary table according to claim 1, wherein the frictional resistance is divided adjacent to the inner wall (12c) and can be reduced. 4. The rotary table as claimed in claim 1, wherein the change is realized in the region of the inner wall (12c) which is bent to a high height when viewed in the direction of movement of the sliver. 5. The rotary table according to claim 1, wherein the friction coefficient μ is reduced. 6. The rotary table according to claim 1, wherein the friction angle α is reduced. 7. A rotary table according to claim 1, wherein the radius of curvature r is increased. 8. The rotary table according to claim 1, wherein the tensile draft is reduced. 9. Device according to claim 1, characterized in that the inner wall (12c) is at least partially composed of a low-friction material. 10. Device according to claim 1, characterized in that the inner wall (12c) is at least partially coated with a low-friction material. 11. Device according to claim 1, characterized in that the inner wall (12c) is at least partially constructed in a segmented structure. 12. Device according to claim 1, wherein the sliver passages (12) are made of a low-friction material. 13. Device according to claim 1, characterized in that the bend of the sliver passage (12) approaches the balloon-like configuration of the sliver path during continuous operation. 14. Device according to claim 1, characterized in that an inlet of the sliver passage (12) is provided. 15. The force acting on the sliver (9, 13) is equal to or greater than the pressing force (P _1, P ₂ ) of the sliver (9, 13) against the inner wall (12c). Device according to one of claims 1 to 14. 16. Device according to claim 1, characterized in that the sliver passages (12) have an at least partially circular cross section. 17. Device according to claim 1, characterized in that the cross section of the sliver passage (12) is at least partially elliptical. 18. Device according to claim 1, characterized in that the cross section of the sliver passage (12) is at least partially polygonal, for example rectangular, square. 19. The frictional resistance at the position (x, y) of maximum contact pressure, ie the sliver (9,
Device according to one of claims 1 to 18, characterized in that the frictional resistance of 13) can be reduced. 20. The device as claimed in claim 1, wherein the outlet of the sliver passage (12) has an elliptical cross section. 21. The device according to claim 1, wherein a magnetic field and / or an electric field is applied to the sliver. 22. Device according to claim 1, characterized in that the tension draft and the movement of the container (11) are coordinated with each other, for example by operational control.