FI60990B - REFERENCE FOR A WHEEL FREQUENCY CONVERTERING WITH A DOUBLE SCREW CONSTRUCTION OF A RING- ELLER SCREW FORMED RAEFFLAD YTTERVAEGG - Google Patents

Description

ESFH ΓβΊ ni.AN ADVERTISING r Π Q Q Π

jggS® LBJ (“') UTLÄGGNINGSSKRIFT 7 7 U

·· §§ (45) IC Patent granted 10 05 1932 (51) 23/04 FINLAND — FINLAND 01) PtMnttlhaktimn - Pu «ntameknln | 750830 (22) Hakamlspllvl —AiMeknln | ad «g 20.03> 75 * * (23) AlkupUvt — Glhlghctadag 20.03.75 (41) Tullut JulklMksi - Bllvlt offantllg 23.09.75

Patent and Registration Office .... , , . ,,.

-. . . . . , (44) Date of departure and date of issue. -

Patent and registration authorities Anaekan utlagd och utl.skriftan publicarad 29.01.82

(32) (33) (31) Pyr * «« y etuoikau * - B ^ sm priority 22.03.7U

Federal Republic of Germany-Förbundsrepubliken

Germany (DE) P 2U13878.I

(71) Wilhelm Hegler, Goethe Str. 2, 873 Bad Kissingen, Federal Republic of Germany (DE) (72) Wilhelm Hegler, Bad Kissingen, Ralph Peter Hegler, Bad Kissingen,

Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) (7 * 0 Oy Kolster Ab (51 *) Method and apparatus for the manufacture of double-walled synthetic tubes with an annular or screw-grooved outer wall räfflad yttervägg

The invention relates to a method of manufacturing double-walled plastic pipes with an annular or screw-like grooved outer wall and a substantially smooth inner wall, in which two concentric tubes are injected from two annular nozzles in one operation, the outer tube being between the molds and in contact with the transverse grooves of the molds, and the inner tube is injected out of another nozzle inside the mold path, whereby air at a pressure higher than atmospheric pressure is introduced both into the space between the two tubes and inside the inner tube, and an apparatus for carrying out this method.

It is known (DE-0S 1 70 * + 718) to manufacture an artificial tube with an annular or helically grooved outer wall and a substantially smooth inner wall, so that in one operation two concentric tubes are injected, whereby the outer tube is guided by the annular nozzles. between the complementary and grooved molds and under the action of a vacuum it is sucked into the mold grooves, and that the inner tube is injected out of the nozzle inside the mold path and brought into contact with the preformed outer tube.

2 60990 In the manufacture of such pipes, it was necessary to supply air from atmospheric pressures to the space between the pipes, because without such support air a vacuum would be created between the two pipes and the inner pipe would be sucked out into the grooves of the outer pipe.

It is also known from U.S. Patent No. 3,280-30 to fabricate such double-walled tubes by dividing the artificial stream from the extruder into two streams coming out directly from the annular nozzles, and supplying compressed air between these annular nozzles and the inner tube. causes design. In the latter method, the control of the artificial flow and the compressed air ratios cause considerable difficulties. According to the previous method, double-walled pipes can be produced, but it has been found that small pipes and high production speeds have difficulties because the pressure differences either suck the inner pipe more or less deep into the outer pipe grooves or swell inwards at these points. The inner wall of such pipes is thus not smooth, but slightly wavy, which considerably increases the flow resistance during the flow of liquids or gases.

It is an object of the present invention to obviate these difficulties and to provide a substantially smooth inner wall of a double-walled tube which has thus not become absorbed in the grooves of the outer tube and has not swelled inwards.

The invention starts from the finding that said difficulties are due to the fact that during cooling, i.e. in the area where the plastic tube is still deformable from the inside, there are pressure differences between the space between the two tubes and the interior which additionally change the shape of the inner tube. If the pipe has a helically grooved outer wall, then this intermediate space forms a duct in communication with the outside air. However, this channel has a considerable length, which e.g.

A 6 cm inner plate pipe with 150 grooves per meter has a pipe length of 28 m per meter, i.e. when a 10 m pipe comes out of the machine, there are already 280 m of ducts. At such large lengths, the pressure fluctuations inside the grooves can no longer equalize in relation to the external pressure, i.e. considerable overpressures or underpressures can occur here depending on whether the air in the grooves is heating or cooling. In annularly closed grooves, pressure equalization with the outside air is not possible at all. Therefore, a smooth inner wall can be achieved only when it is possible to control the manufacturing process so that at least in the area where the inner tube changes from a plastic, deformable state to a solid state, there is the same pressure in the space between the two tubes as inside the inner tube. According to the invention, this is achieved so that the temperature and pressure of the air introduced into the interior of the inner tube can be controlled independently of the temperature and pressure of the air introduced into the space between the pipes, at least the temperature of the air introduced into the space between the pipes is raised relative to the outside temperature, and higher than the softening temperature of the fed plastic.

3 60990

Other aspects of the method are set out in subclaims 2-U. The device according to the invention, in turn, is characterized in that the inner tube mandrel belonging to the injection tool has a bore for conducting air separately to the inner tube interior and that the outer tube mandrel belonging to the spray tool has a bore for conducting air separately to the space between the two tubes.

Other device-specific aspects are set out in subclaims 6-9.

It is also known to make the mandrel extension placed on the mandrel of the spray nozzle for the inner tube such that the inner tube is smoothed against the outer tube as a result of this mandrel extension and the two tubes are made very welded together (German Patent Specification 1,707,818). In these known devices, it is difficult to center the mandrel extension so well in the mold path that the wall thickness of the resulting double-walled tube is uniform over the entire circumference. The unevenness in the artificial material flow can also press the mandrel extension to the side, which then remains in this position, resulting in a pipe with an uneven wall thickness. These difficulties can also be avoided by means of a device as defined in the requirements.

The invention will now be described in more detail by means of an example described in the drawings, in which: Figure 1 shows an apparatus for carrying out the method according to the invention; Figures 2-k show cross-sectional views of the wall of a finished, double-walled pipe under different pressure conditions; Fig. 5 shows an embodiment of a self-positioning bearing weighing device with a polished ironing ring; Figure 6 shows an embodiment with barrel-shaped rollers; Fig. 7 is a sectional view taken along line IV of Fig. 6; and Fig. 8 is a sectional view taken along line V of Fig. 6.

In the device according to Fig. 1, an outer tube 1 is injected from a nozzle 2 with a mandrel 3 and an inner tube U from a nozzle 5 with a mandrel 6. This inner mandrel 6 has a central longitudinal bore 7 through which air is discharged through the bores 8 into the interior of the tube 1+ , which is separated from the outside by a mandrel extension 9, which will be described in more detail below. This air is hereinafter referred to as the support air B, between the outer tube spray tool mandrel 3 and the inner tube spray tool nozzle tube 5 there is an annular duct 10 through which air is supplied. This air is discharged from the discharge opening of the annular channel 10 and flows into the space 11 between the plastically * deformable synthetic tube 1 and the nozzle tube 5, which is in front of the discharge opening of the nozzle 5. This air is hereinafter referred to as the support air A, the supply of the support air A to the annular duct 10 takes place via an oblique bore 12.

A non-displayed heater is used to preheat the support air to the required temperature. The measuring instruments 13, 11 * measure the pressure and temperature of the support air A. The temperature measurement can then take place directly at the location of the measuring device, while the pressure is preferably measured inside the spray tool, approximately at 15, 11 60990 because the support air flows from this point through a duct with a relatively large cross-sectional area and low flow resistance, so that the pressure of the support air no longer changes substantially from point 15 to the point where it discharges from the nozzle, the support air B is supplied to the bore 7 of the mandrel 6 via the side bore 16. Here, too, there are measuring devices 1T »18 in front of the inlet, which measure the pressure of the support air 2 and the temperature which is heated to the required temperature by a heater not shown. The pressure measuring point of the support air B is also preferably inside the injection tool, approximately 19.

The thermoplastic outer tube coming out of the nozzle 2 is introduced into the path of the circulating molds 20 in a known manner. When the molds are closed, the grooves machined in the molds come into contact with the suction channel 2 in a known manner. , which exists between a significantly lower atmospheric pressure and an internal pressure of about 0.5 ~ 3% higher than atmospheric pressure. The support air A then enters the grooves of the outer tube according to the arrows 22. The molds 20 are cooled from the outside so that the outer tube cools relatively quickly as soon as it settles on the inner wall of the grooves. After exiting the nozzle 5, the inner tube H becomes expanded when the pressure of the support air B exiting the openings 8 is slightly higher than the pressure in the space 11, and settles on the already stiffened outer tube 11. The mandrel extension 9 makes the inner tube k smoothed against the outer tube 1 together, the mandrel extension 9 at the same time maintains a small overpressure generated when the support air B discharges from the openings 8.

In order for the outer and inner tubes to be welded together well, it is desirable that the inner tube settles on the outer tube as quickly as possible, i. as soon as the shaping of the outer tube is completed, and the inner tube should settle on the outer tube already in the second - third groove after the suction has started. During the continuous movement of the molds, the outer tube resting on the water-cooled mold wall cools rapidly, but the inner tube, which the Air Cushion separates from the cooled mold, cools more slowly and therefore remains plastically deformable longer. The air in the grooves cools slowly when it contacts the cooling outer tube, at the same time reducing the pressure. If the pressure decreases too much so that there is a lower pressure inside the grooves than inside the inner tube, the inner wall 23 is pulled slightly inside the irons. If, on the contrary, the air pressure in the grooves is too high, as shown in Fig. 3, the inner wall conveys slightly outwards at 2k. If the temperature and pressure of the support air A and the support air B are determined correctly, so that when the inner wall solidifies the grooves are the same as the pressure inside the inner tube, so the inner wall remains smooth according to Fig. H and the flow resistance does not deteriorate. Experiments have shown that the state shown in Fig. H can be achieved even when a thin film having a thickness of up to 0.05 mm is injected as an inner wall. Such a small thickness of the inner wall not only means a considerable saving of material, but also that the inner wall does not impair the flexibility of the tube, so that such a double-walled tube is practically as flexible as known transversely grooved tubes without a second inner wall.

Attached to the mandrel 6 is a mandrel extension 30 which bears a self-positioningly mounted cylinder 9 · To compensate for the weight of the cylinder 9, a leaf spring 32 * is placed in the air gap between the mandrel extension 30 and the cylinder 9. The bias is just sufficient to compensate the cylinder 9. The closure plate 33, secured by a nut 34, locks the cylinder 9 against longitudinal displacement and seals the gap between the cylinder 9 and the mandrel extension 30. Outside the cylinder 9 there are helically extending grooves, which are preferably arranged in multiples and which extend opposite the helical grooves of the molds 20. Due to the slightly increased pressure of the support air supplied to the space 36 through the bore 7, the air between the inner tube 4 and the cylinder 9 tends to escape. Thanks to the helical grooves, a vortex formation is achieved so that an air cushion is formed between the cylinder 9 and the inner tube 4. This makes it possible to slightly reduce the diameter of the cylinder 9, i. the diameter of this cylinder may be smaller than the inside width of the finished synthetic tube. Since the inner tube 4 in this case does not touch the cylinder 9 at all but moves away from it due to the connected air cushion *, this device can be used to produce double-walled tubes with a very thin inner wall, the thickness of which can be reduced to 0.05. Such double-walled tubes have the advantages of low total weight and low material consumption as well as vertical compression strength and smooth inner surface, but in addition to these advantages they have the advantage that the inner wall hardly degrades the flexibility of the tube compared to a waveguide without an inner wall.

Figure 5 shows a second embodiment of a weighing device in a slightly different form of spraying device.

A weighting device 41 is placed on the mandrel extension 40 attached to the mandrel 6, leaving a gap 42 between the mandrel extension 40 and the ring 41, which allows the ring 41 to move in a plane perpendicular to the axis of the spray tool. The screw ring 43 prevents axial displacement of the ring 41 and at the same time acts as a seal which prevents compressed air from escaping through the gap 42. In order to make the self-positioning bearing even in all directions regardless of the weight of the ring 41, there is a spring 44 between the mandrel extension 40 and the ring 41, the bias of which is just so great as to just equalize the weight of the ring 41 when the ring gap 42 is equal at the top and bottom. Of course, when installing the mandrel, it must be taken into account that the spring 44 is always in a perpendicular plane extending through the axis of the mandrel and above this axis.

6 60990

Figure 6 shows a device suitable for the manufacture of pipes with a thick inner wall. The arrangement of the nozzles and the support air supply ducts here corresponds to the arrangement of Fig. 5 and is denoted by the same reference numerals. Attached to the inner mandrel 6 is again a mandrel extension 40 which self-positionally carries an ironing ring 41, the weight of which is compensated by a compression spring 44 · This device, which is only pre-ironed and can also be omitted, also has a self-positioning bearing, barrel-shaped pressure roller 50 , 51 · These rollers are pivotally mounted on a roller ring bearing ring 52 which is supported against a mandrel extension 55 by means of a compression spring 53 and a ball 54. In the embodiment, four rollers are placed per plane vertically with respect to the longitudinal axis of the sprayer, and the two groups of rollers are displaced so that the rollers 51 of the second group of rolls press the inner tube points against the outer tube not yet gripped by the rollers 50 of the first group. Each individual roll is mounted on a roller head bearing ring 52 on a shaft 56 in an easily pivotable manner on a ball bearing 57. The displacement of the roller shafts is prevented by locking pins 58. The bias of the spring 53 is dimensioned so that the entire weight of the roller head has just been compensated in the centered position. The diameter of the roller ends is preferably such that at the points where the inner wall is welded together with the outer wall, the total thickness of the synthetic layer is equal to the outer tube wall thickness, so that at these points the wall thickness is not the sum of the inner and outer wall thickness. the rollers press the inner wall too much to the side of the substance. When the pipes are to be used as drainage pipes, this facilitates the cutting of the openings.

If an adhesive with a tendency to stick is used, it is expedient to provide all the parts in contact with the inner wall, i.e. the ironing ring 41 »cylinder 9 and the rollers 50, 51, with a surface coating formed by tetrafluoropolyethylene.

J *

Claims (9)

A method of producing double-walled plastic tubes having annular or helical grooved outer wall and substantially screened inner wall, in which two concentric tubes in one operation are ejected from two annular nozzles, the outer tube being withdrawn from the first nozzle after withdrawal from the first nozzle. transverse grooves are provided and together form a heel-forming molds and are brought into contact with the transverse grooves of the molds, and the inner tube is ejected from the second nozzle located inside the mold, whereby air, vane pressure exceeds the atmospheric pressure, the space between the two tubes is added as well. the inner tube, characterized in that the temperature and pressure of the air brought into the interior of the inner tube can be controlled independently of the temperature and pressure of the air supplied to the space between the two tubes, that at least the temperature of the air space the air supplied between the two tubes is increased with respect at the outer temperature, and that the temperature of the air supplied to the space between the two tubes is at least equal to the softening temperature of the applied plastic. Method according to claim 1, characterized in that the temperature of the air supplied to the interior of the inner tube is below the temperature of the air supplied between the two tubes. Method according to claim 1 or 2, characterized in that the pressure of the air supplied to the interior of the inner tube exceeds the pressure of the air supplied between the two tubes. ! +. Method according to any one of claims 1-3, characterized in that the pressure of the air supplied to the interior of the inner tube exceeds the pressure of the air supplied between the two tubes and the temperature of the interior of the inner tube. The air supplied while taking into account the temperature of the air supplied to the space between the two tubes is chosen so that upon cooling of the outer tube below the softening point of the area in which the inner tube is still plasticly moldable, the near-same pressure that raises ice airona area in the interior of the inner tube. Apparatus for carrying out the method according to any of claims 1-1 +, with two annular nozzles, from which two concentric tubes are sprayed, and with circularly controlled, with transverse grooves and together with a heel-forming mold, from which air is extracted. and with air supply means for introducing air between the two tubes and into the interior of the