DE1939402B2 - Method and device for corrugating pipe walls - Google Patents

Description

The invention relates to a method for corrugating the wall of pipes, preferably that of Metal tubes for sheaths of electrical cables with large diameters and thick walls where the waves begin at one point on the pipe circumference and constantly around the circumference progressive pressure effect by forming the wave troughs with simultaneous shortening of the Pipe wall in the pipe's longitudinal axis and leaving the material sections lying between two valleys be formed on the original pipe diameter, as well as a device for implementation this method with a corrugated gear rotating around the tube, which is concave on the circumference with several Printing tools is equipped and that during the pipe feed around an axis at right angles to the The longitudinal axis of the pipe rotates.

Corrugated metal tubes should be designed for use as a cable jacket so that mechanical and electrical protection, a high degree of flexibility and transverse rigidity for the cable is achieved.

A precise examination of the phenomena that occur when a pipe or cable jacket is corrugated and events shows that it is not possible with the known device to use metal pipes to corrugate large diameters and high wall thicknesses in such a way that no Wall thickness reduction and thus additional material hardening occur. Even those for a high Flexibility the greatest possible corrugation depth can be achieved in the cases described with the known device not manufacture.

The invention is based on the object of providing metal pipes, in particular metal pipes with large diameters (greater than 40 mm) and high wall thicknesses (greater than 4% of the diameter) so that the deformation of the pipe walls without stretching, thus without reducing the wall thickness and from this following hardening of the material and without a reduction in diameter the non-corrugated pipe parts takes place.

According to the invention, this object is achieved in that the tube is in the still undeformed area contrary to the direction in which the first wave trough is formed, is deflected in one Dimension at which the pipe does not yet buckle.

In the device according to the invention for performing this method is before and after Corrugated gear, seen in the direction of the pipe, a bearing for the pipe in the manner of a segmented ball socket movable ball head arranged with a central passage opening for the pipe, and the distance the pressure tools on the circumference of the corrugated gear has such a degree that only one Pressure tool on the pipe performs deformation work, with the center of the in the area of the undeformed Tube lying bearing out of the tube axis to be offset radially in the direction of the corrugated gear axis is.

Further design features of the device according to the invention are that the bearings in different Distances from the printing tool are arranged, the distance of the corrugated part of the Pipe supporting bearing from the location of the pressure tool in the corrugated gear is at least 1.5 times the pipe diameter is and the distance of the non-corrugated part of the pipe supporting bearing from The location of the pressure tool in the corrugated gear is at least 2.5 times the pipe diameter.

In the design of the rotating corrugated gear, it has proven to be advantageous if the radius of curvature R of the concave pressure tools located in the rotating corrugated gear is in a ratio between 1.1 R ₀ and 1.8 R ₀ to the radius R _{0 of the non-corrugated tube} .

The diameter D _{w of} the corrugated gear also has a decisive influence on the deformation work. It results from the predetermined construction data of the corrugated pipe according to the formula

t + r (1 - cos <x)

Thereby means

D _w = diameter of the corrugated gear, measured over the pressure tools in the center of the concave curvature;

S = distance of the tube shafts from each other;

t = wave depth of the tube waves; (

r = radius of the pressure tool, which is equal to the radius of the pipe corrugation determined by the construction of the corrugated pipe;

oil = angle between two adjacent printing tools.

For many applications, especially when combining a shaft device designed according to the invention with a continuously operating pipe welding machine or pipe press, it is desirable that the distance of the corrugated gear from the tube to be corrugated and thus the corrugation depth during of the company can be changed. This is done using a rotating ring and slip rings remotely controlled motor, which changes the distance between the corrugated gear and the pipe via a spindle can. With this spindle, a corresponding shift of the unbalance of the Corrugated wheel compensating counterweight are effected.

According to the previously explained, there is one for each pipe diameter and each wave shape Corresponding corrugated gear necessary. To simplify storage and tool construction and thus To reduce tool costs, the following measures have proven to be useful:

The pressure tools are inserted into the grooves of the corrugated gear and attached by conical washers supported on both sides of the corrugated gear so that they can be easily replaced.

For the production of helically corrugated tubes, the pressure tools are around a radial Axis rotatably attached to the corrugated gear, the rotation takes place by offsetting the above-mentioned guide grooves containing retaining disks or by seated at the lower end of the tool holder Bevel gears or bevel gear segments that can be rotated together using a bevel gear.

For the production of very deep corrugations, the pressure tool must be as perpendicular as possible to the pipe surface hit. This can be achieved in that the printing tools are rotatable about a Axis parallel to the axis of rotation of the corrugated gear is attached to the corrugated gear and always via a planetary gear can be controlled into a position in which they impinge on the pipe surface at right angles.

Different shaped pressure tools can also be used in the corrugated gear, so that in the Tube grooves with periodically changing intervals, different depths or shapes and grooves with changing angles to the pipe's longitudinal axis can be generated. The angle of the rollers to the longitudinal axis of the pipe can be different from 90 ° (annular corrugation) (helical corrugation).

The service life of the printing tools can be increased considerably if lubricant is supplied during the deformation takes place. In order to keep the consumption of lubricant as low as possible, the device designed so that the lubricant supply through a bore in that pressure tool takes place, which is in engagement, while in the non-engaged printing tools through a slide, the lubricant supply is interrupted. The lubricant supply can also through a specially designed nozzle rotating with the corrugated wheel, which lubricants only to the ao Promotes places where a pressure tool is in engagement. This nozzle can also be where the imbalance of the corrugated gear compensating counterweight sit, which then appropriately similar to the corrugated gear can be designed.

The advantages that can be achieved with the invention are that with a structurally simple device almost any shape of corrugation in tubes made of any plastically deformable material with any Diameters and wall thicknesses can be generated and that this corrugation simultaneously with bending of the pipe takes place without stretching and thus thinning and hardening of the pipe wall.

Embodiments of the invention are shown in figures. It shows

Fi g. 1 a schematic representation of the device,

Fig. 2 is a partial view of the corrugated wheel,

F i g. 3 a schematic representation of the corrugated gear,

4 shows a revolving Weihrad with counterweight and adjustment,

Fig. 5 is a partial view of a corrugated gear whose Printing tools can be arranged at different angles,

6 shows a partial view of a corrugated wheel, the pressure tools of which have a common bevel wheel can be adjusted,

7 shows a schematic representation of a corrugated wheel, whose printing tools are always placed at right angles to the pipe axis via a planetary gear will,

8 shows a corrugated tube with alternating groove spacing,

9 shows a corrugated tube with periodically changing Groove spacing,

10 shows a corrugated pipe with different depths and shapes of the pipe grooves,

11 shows a corrugated tube, the grooves of which are helical get lost; this figure was submitted later.

In the device shown in FIG. 1, the tube 1 to be corrugated runs past the rotating corrugated wheel 2, the corrugated wheel rolling on the tube. In each case a pressure tool 3 bends the tube 1 to be corrugated a little away from the WeUrad 2 and uses the resulting tendency to kink a part of the tube wall 7 to form the groove. Only when the groove is fully formed does the next pressure tool 3 attack, since it would hinder the flow of the material of the pipe wall 7 beforehand. The movable bearings 6 a and 6 b in the manner of a ball head movable in spherical segment sockets allow extensive deflection of the tube 1. To compensate for the different flexibilities of the corrugated and the non-corrugated tube, the distance A _{2 of} the bearing 6 a from the re-running pressure tool 3 must be greater than 2.5 times the pipe diameter D, while the distance A _{1 of} the bearing 6 b from the re-running pressure tool 3 must be greater than 1.5 times the pipe diameter D.

Fig. 2 provides information on the structural design of the corrugated gear 2 and the pressure tools 3. The pressure tool 3 is concave in the plane of the figure. The radius R of this concave curvature is between 1/1 times the radius of the non-corrugated tube R ₀ and 1.8 times the radius of R ₀ . The lower part of the pressure tool 3 is mounted in grooves 11 of the corrugated gear 2, while the attachment of the pressure tool 3 is carried out by two internally conical disks 12 and 13 which are screwed onto the corrugated gear.

Fig. 3 gives instructions for the dimensioning of the corrugated gear 3 depending on the design data of the desired tube corrugation. The diameter D _{w of} the corrugated gear 2, measured over the center of the concave curvature of the printing tools 3, is given by the formula already given

t + r (l - cos «)

certainly. It is

S = distance of the tube shafts from each other;

t = depth of the tube waves;

r = radius of the rounding of the printing tools 3, which is equal to the desired radius r at the bottom of the tubular shafts;

α = angle between two pressure tools 3 on the circumference of the corrugated gear 2, which in turn results from the geometry of the desired tubular waves.

F i g. 4 outlines a possible arrangement of rotating corrugated gear 2 and the imbalance of the corrugated gear compensating counterweight 10, the distance of which from the tube to be corrugated via the spindle 8 can be set in the same direction. So that this adjustment can take place during operation, the spindle 8 is driven by a remotely controlled motor 9, for example powered by slip rings. The possible lubrication of the printing tools 3 by bores is also indicated in FIG. 4 22 in the printing tools 3 or by a rotating nozzle 23, which in this case is in Counterweight 10 is attached.

Fig. 5 shows a further embodiment of the invention, in which the printing tools 3 are arranged in enlarged grooves 11 of the corrugated gear 2. The angle β of the printing tools 3 to the pipe longitudinal axis 5 is determined here by the retaining washers 16 and 17, which guide grooves 14 carry. By turning the retaining washers 16 and 17 against each other the printing tools are rotated about a radial axis 15.

If the angle β needs to be changed more frequently, use is expediently made of an embodiment of the device according to FIG. To sit here

the printing tools 3 on brackets 18 which are rotatably arranged about the radial axis 15 and which have a bevel gear attached to its foot or bevel gear segment 19 can be adjusted. Adjustment and These bevel gears or bevel gear segments are fixed by the bevel gear 20.

Suitable for the production of pipes with extremely deep corrugations and / or with steep wave flanks an embodiment of the corrugated gear according to FIG. 7. Here the printing tools 3 are around an axis of rotation of the corrugated gear 2 parallel axis 21 rotatably mounted. A planetary gear 24 controls the position of the printing tools 3 in such a way that they always strike the pipe surface 7 at right angles.

FIGS. 8, 9, 10 and 11 show corrugated tubes made with the apparatus described. F i g. 8 shows a corrugated pipe, the grooves of which have different distances from one another. F i g. 9 shows a corrugated pipe in which the grooves are arranged in groups with cylindrical pipe parts in between. This form of tubular shaft offers new possibilities for the designers of coaxial cables. Furthermore, fittings and terminations can be attached particularly easily to the cylindrical pipe parts. F i g. Fig. 10 shows a corrugated tube, the individual grooves of which have different depths and shapes. 11 shows a possibility of tube corrugation resulting from a change in the angle β between the pressure tool and the longitudinal axis of the cable. With the device described, it is also possible to produce helical grooves.

Claims (12)

Patent claims: 1. Method for corrugating the wall of pipes, preferably of metal pipes for Sheath of electrical cables with large diameters and thick walls, in which the waves beginning at one point on the pipe circumference and continuously progressing around the circumference The effect of pressure by shaping the wave troughs while at the same time shortening the pipe wall in the pipe's longitudinal axis and leaving the material sections between two valleys be formed on the original pipe diameter, characterized in that the tube in the still undeformed area opposite to the direction in which the first wave trough was formed is, is bent to a degree at which the pipe does not yet buckle. 2. Apparatus for carrying out the method according to claim 1 with a corrugated gear rotating around the tube, which is equipped on the circumference with several concave pressure tools and which rotates about an axis at right angles to the pipe longitudinal axis during the pipe advance, characterized in that in front of and behind the corrugated gear (2), seen in the direction of the pipe, each bearing (6 a, 6 b) for the pipe (1) is arranged in the manner of a spherical head movable in spherical segment sockets with a central passage opening for the pipe (1) and that the distance between the pressure tools ( 3) at the circumference of the flute (2) has a dimension at which only one pressure tool (3) on the tube (1) performs deformation work, the center of the bearing located in the area of the undeformed tube radially out of the tube axis in the direction is offset on the corrugated gear axis. 3. Apparatus according to claim 2, characterized in that the bearings (6 a, 6 b) are arranged at different distances (A) from the printing tool (3), the distance (A 1) of the bearing supporting the corrugated part of the tube ( 6 b) from the location of the pressure tool (3) in the corrugated gear (2) is at least 1.5 times the pipe diameter (D) and the distance (A 2) of the bearing (6 σ) supporting the non-corrugated part of the pipe from the location of the pressure tool ( 3) in the corrugated gear (2) is at least 2.5 times the pipe diameter (D). 4. Apparatus according to claim 2 or 3, characterized in that the radius of curvature (J?) Of the concave pressure tools (3) seated in the rotating corrugated gear (2) in a ratio within the limits between 1.1 Ji ₀ and 1.8 R ₀ to the radius (R ₀ ) of the non-corrugated pipe. 5. Device according to one of claims 2 to 4, characterized in that the diameter (D _w ) of the corrugated gear according to the formula C2 D ", = t + r (1 - cos α) is chosen in which D _w = diameter of the corrugated gear, measured over the pressure tools in the center of the concave curvature; S = distance of the tube shafts from each other; t = wave depth of the tube waves; r = radius of the pressure tool, which is equal to the radius of the pipe corrugation determined by the construction of the corrugated pipe; α = angle between two adjacent printing tools. 6. Device according to one of claims 2 to 5, characterized in that for changing the distance between the corrugated wheel (2) and the tube (1) to be corrugated during operation (8) is provided, which is driven by a remote-controlled motor (9), said spindle (8) at the same time a corresponding displacement of a counterweight to compensate for the imbalance (10) causes. 7. Device according to one of claims 2 to 6, characterized in that the holder the pressure tools (3) inserted in the grooves (11) of the corrugated wheel (2) by means of conical disks (12, 13) takes place on both sides of the corrugated gear (2). 8. Device according to one of claims 2 to 7, characterized in that the printing tools be attached to the corrugated gear (2) so as to be rotatable about a radial axis (15), the rotation by offsetting the retaining disks (16, 17) containing guide grooves (14) with respect to one another takes place (FIG. 5) or by means of bevel gears seated at the lower end of the tool holder (18) (19) or bevel gear segments which can be rotated together via a bevel gear (20) (FIG. 6). 9. Device according to one of claims 2 to 6, characterized in that the printing tools (3) rotatable about an axis (21) parallel to the axis of rotation of the corrugated gear (2) on the corrugated gear (2) attached and via a planetary gear (24) can always be steered into a position in which they impinge on the pipe surface (7) at right angles. 10. Device according to one of claims 2 to 9, characterized in that the in the corrugated gear (2) attached pressure tools (3) are designed differently with respect to the distance from each other, outer shape and angle (ß) to the pipe longitudinal axis for generating grooves with periodic changing distances, different depths or shapes as well as grooves with changing angles to the pipe's longitudinal axis; the angle ß) of the tools to the pipe longitudinal axis can be different from 90 ° (annular corrugation) (helical corrugation, Fig. 8 to 11). 11. Device according to one of claims 2 to 10, characterized in that the lubricant supply through the respective engaged pressure tool (3) the pressure tools have a bore (22) through which the lubricant exits. 12. Device according to one of claims 2 to 10, characterized in that the lubricant supply through a nozzle (23) rotating with the corrugated wheel (2), which lubricant only promotes to the points at which a pressure tool (3) is in engagement, this nozzle also in which the imbalance of the corrugated wheel compensating counterweight (10) can sit, which can be designed similar to the corrugated gear. For this purpose 2 sheets of drawings 009 549/84