JP2008247613A - Rotary table for storing sliver, especially in draw frame, combing machine, or the like - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce a frictional resistance between a sliver and a sliver passage. <P>SOLUTION: This rotary table for storing a sliver, especially in a draw frame and a combing machine is equipped with an entrance 12a and exit 12b for the sliver, 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 draw frame, a combing 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 12. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The invention comprises a sliver inlet and outlet, wherein the inlet is located near or on the axis of rotation and the outlet is located radially and axially away from the inlet and is spatially bent The sliver has a sliver passage, a tensile draft acts on the moving sliver via the sliver, there is a relative movement between the moving sliver and the inner wall of the sliver passage, and the inner wall of the sliver passage acts a frictional resistance, In particular, the present invention relates to a rotary table for a sliver storage device such as a kneader or a carding machine.

  In operation, the sliver in the sliver passage undergoes several movements and is subjected to several forces. Between the take-off roller and the self-moving container, the sliver receives a known feed draft, i.e. a traction force is applied, which moves the sliver from the inlet to the outlet. Because the outlet is located axially away from the inlet, additional rotational force acts laterally outward on the sliver due to rotational movement, which is unexpectedly unjustified by “bulging”. May produce force. The outwardly acting centrifugal force is reduced by reducing the distance of the bending sliver passage relative to the axis of rotation, i.e. the "bulge" in which the inner wall acts as a reaction force on the sliver is reduced. The reaction force causes high friction of the fiber material with the inner wall, thereby impairing the speed of movement of the sliver and also does not eliminate undue drafting that causes friction.

  A rotating table with a curved sliver passage made of polished special steel has been proposed for delivery speeds up to 1000 m / min. However, it has been found that this method does not allow a continuous increase in sliver travel speed exceeding 1000 m / min. Particularly in delicate kneader slivers, the large frictional force on the inner wall produces an undesired unjust draft.

  On the other hand, the present invention is based on the problem of preventing the above-mentioned drawbacks, and in particular to provide a rotary table of the technique described at the beginning which makes it possible to improve sliver guidance and sliver quality.

  This problem is solved by the configuration of the characterizing portion of claim 1.

  The treatment according to the invention allows for the various movements of the sliver in the interior space of the sliver passage and the action of various forces on the sliver. The acting force does not occur at the same magnitude in all locations. To that end, by changing the interaction and / or arrangement between the sliver and the inner wall, undesirable or disturbing forces can be dealt with partly and individually. In this way, a substantial improvement in sliver guidance and sliver quality is achieved, and a considerable increase in sliver travel speed in excess of 1000 m / min, especially in a kneader can be achieved. To the same extent, the improvement of sliver guidance according to the invention makes it possible to improve the sliver quality under sliver movement speeds below 1000 m / min, especially in carding machines. The sliver is essentially homogeneous, i.e. uniform with respect to the draft in the various sections or regions. The partial draft in the sliver passage and its effect on the sliver section or region are uniform and the tensile draft is improved as a whole.

  Claims 2 to 21 contain advantageous further configurations of the invention.

  The invention is explained in more detail below on the basis of the 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 area 4 of a kneader, for example a crutcher type kneader HSR. In the introduction area 1, a sliver sliver container (round container) 5 having two container rows is arranged below the sliver introduction table 6 (creel), and the supply sliver 7 is provided via an introduction roller 8. It is pulled in and introduced into the draft roller 3. After passing through the draft area 3, the stretched sliver 9 reaches the rotary table 10 of the sliver container storage 4 and is delivered into the outlet container 11 in a ring shape. A sliver passage 12, such as a curved pipe, is disposed in the rotary table 10, and the sliver 9 moves through the sliver passage 12. Reference symbol A indicates the working direction of the kneader. Reference numerals 17a and 17b indicate calendar rollers.

  2 includes a supply roller 21, a supply base 22, a take-in roll 23, a cylinder 24, a doffer 25, a take-up roller 26, a squeeze roller 27, 28, a fleece guide 29, a trumpet 30, a delivery roller 31, 32 flat bar 34. FIG. 2 shows a carding machine provided with a rotating flat 33, calendar rollers 17a and 17b, a sliver container 11 and a sliver container storage area 20, for example, a crutcher type high-performance carding machine. The direction of rotation of the roller is indicated by a curved arrow. The operating direction of the carding machine is indicated by the symbol B. There is a housing above the cover plate of the sliver container storage place 20, and there is a rotating table 10 that rotates. The sliver container 11 is moved by a driving device (not shown) while the sliver 13 is filled through the rotary table 10. A sliver passage 12, for example, a curved pipe, is disposed 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 disposed coaxially with the rotational axis 16, and the outlet 12b is disposed at a radial distance a and an axial distance b with respect to the inlet 12a. The turntable 10 is disposed in a fixed panel 14. The turntable 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). Ball bearings are indicated by reference numerals 15a and 15b.

The sliver 9 receives a light tensile draft in the sliver passage 12, that is, a traction force Z acts. While passing, the sliver 9 follows the bending of the sliver passage 12. Due to the bending and the traction force, the sliver 9 exerts a pressing force, that is, frictional force P ₁ , P ₂ on the inner wall 12 c of the sliver passage 12 in the regions x and y except for the remaining position of the inner wall 12. Relative motion occurs between the traveling sliver 9 and the inner wall 12c.

According to the present invention, the frictional resistance between the sliver 9 and the inner wall 12c is reduced by the interaction between the sliver 9 and the inner wall 12c of the sliver passage 12 and / or a change in the spatial arrangement. The “critical” regions x, y of the inner wall 12c have important significance here. Accordingly, the friction between the sliver 9 and the regions x and y of the inner wall 12c can be reduced by decreasing the friction coefficient μ, decreasing the friction angle α, and / or increasing the curvature radius r. The tensile draft determined by the calendar rollers 17a and 17b and the weight of the container 11 can also be changed (tensile force Z). By this treatment, the pressing forces P ₁ and P ₂ are reduced individually or in combination. The same applies to the sliver 13 in FIG.

  The delivery of the sliver 9 is carried out by the rotary table 10 having a role of placing the sliver 9 and 13 produced by the sliver forming machine in an annular manner in the sliver container 11. The annular formation is performed by a combination of two rotational movements, a fast movement performed by the rotary table 10 and a slow movement performed by the sliver container 11 (in the case of a rectangular container, the second movement is translational). ). In the sliver storage process, the slivers 9 and 13 in the sliver passage (tube) 12 are subjected to various forces. Gravity, centrifugal force, biasing force due to the applied tensile force, and frictional force between the sliver 9 and 13 and the pipe inner wall 12c acting in a direction opposite to the moving direction of the sliver 9 and 13 thereby impeding the sliver storage process. Acts. The tensile draft is measured to obtain an accurate delivery situation, so that the sliver in the sliver passage 12 is always subject to some tension. In this way, the sliver always leans against the small radius portion bent to the middle and high of each curved portion in the bending region of the sliver passage 12. The frictional forces described above are substantially caused by the interaction between the sliver and the tube in this contact area x, y. The aforementioned adverse effects on the machine operating condition and sliver quality are caused, inter alia, by this friction between the sliver 9 and the inner wall 12c of the sliver passage 12 guiding it.

  In order to improve the sliver guide in the sliver passage 12 of the turntable 10, the following treatments are performed individually or in combination.

  Reduction in the degree of friction between the fiber material and the inner surface 12c of the sliver passage (tube) 12 implemented from a segmented or low friction material for each segment. In this way, for example, the tension is reduced, thereby preventing undue drafting.

  The geometric shape of the sliver guide organ is changed so that the loosening of the fiber material is prevented by the peripheral surface of the sliver passage (sliver guide organ) 12.

  The geometric shape of the sliver guide organ 12 is expanded especially at the inlet 12a. As a result, the relaxation phenomenon caused by the sliver passage (sliver guide organ) 12 of the slivers 9 and 13 under the influence of tension is minimized.

  An 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 fiber and the surface 12c guiding the fiber.

  The sliver load variation caused by sliver storage is adjusted by controlled factors, such as containers.

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

  The sliver passage (sliver guide organ) 12 has a different shape from the round implementation shape (eg oval).

  The treatment for reducing the comparative relaxation in the sliver passage (sliver guide organ) is applied to a kneader, a carding machine, and a comber.

FIG. 1 is a side view showing a kneader equipped with a rotary table according to the present invention. FIG. 2 is a side view showing a carding machine equipped 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. FIG. 4 is a sectional view showing a side surface of the sliver passage together with the sliver. FIG. 5 is a plan view showing the sliver passage.

Explanation of symbols

9 Sliver 10 Rotary table 11 Container 12 Sliver passage 13 Sliver

Claims (21)

A spatially bent sliver passage comprising a sliver inlet and outlet, the inlet being arranged near or on the axis of rotation and the outlet being arranged radially and axially away from the inlet; Rotation for the sliver storage device, in which the sliver is under tensile draft, and there is a relative movement between the moving sliver and the inner wall of the sliver passage, and friction resistance acts on the sliver through the inner wall Changing the interaction and / or spatial arrangement between the sliver (9, 13) and the inner wall (12c) of the sliver passage (12), the frictional resistance is at least partially reduced;
The rotary table characterized in that the frictional resistance can be partially reduced adjacent to the inner wall (12c).   The rotary table according to claim 1, wherein the frictional resistance can be reduced by being divided adjacent to the inner wall (12c).   The turntable according to claim 1 or 2, characterized in that the change is realized in a region of the inner wall (12c) bent to a middle height when viewed in the moving direction of the sliver.   4. The rotary table according to claim 1, wherein the friction coefficient [mu] is reduced.   The rotary table according to claim 1, wherein the friction angle α is reduced.   6. A rotary table according to claim 1, wherein the curvature radius r is increased.   7. The rotary table according to claim 1, wherein the tension draft is reduced.   8. A device according to claim 1, wherein the inner wall (12c) is at least partly composed of a low friction material.   9. A device according to claim 1, wherein the inner wall (12c) is at least partially coated with a low friction material.   10. A device according to claim 1, wherein the inner wall (12c) is at least partly composed of a segmented structure.   Device according to one of the preceding claims, characterized in that the sliver passage (12) is made of a material with low friction.   12. The device according to claim 1, wherein the bending of the sliver passage (12) is close to the balloon-like configuration of the sliver path during continuous operation.   Device according to one of the preceding claims, characterized in that an inlet for the sliver passage (12) is provided. Force acting on the sliver (9,13) is, the inner wall pressing force of the sliver (9, 13) to (12c) (P _1, P ₂₎ to equal being greater than claims 1 to 13 The device according to one of the above.   15. A device according to claim 1, wherein the sliver passage (12) has an at least partly circular cross section.   Device according to one of the preceding claims, characterized in that the cross section of the sliver passage (12) is at least partly elliptical.   17. Device according to one of the preceding claims, characterized in that the cross section of the sliver passage (12) is at least partly polygonal, for example rectangular or square.   The frictional resistance at the position (x, y) of the maximum contact pressure, that is, the frictional resistance of the sliver (9, 13) against the inner wall (12c) can be reduced. The device described.   19. The device according to claim 1, wherein the outlet of the sliver passage (12) has an elliptical cross section.   Device according to one of the preceding claims, characterized in that a magnetic and / or electric field is applied to the sliver.   21. The device according to claim 1, wherein the pulling draft and the movement of the container (11) are coordinated with one another, for example by operational control.

Images