DE1554993C - Method and device for cooling an extruded, tubular body - Google Patents

Description

1 ■ - .; ■■ '"2

The invention relates to a method for cooling the hose is neither achievable nor an extruded, tubular body, in view of the fact that only a comparatively small circumference, in particular of a jacket encasing a strand, comes into contact with the liquid,
in which the tubular body is brought into contact with a liquid, the object of the invention is, on the other hand, the creation of a method and a device with the liquid level inclined with respect to the horizontal, the aid of which a gentle introduction is more sensitive. The subject matter of the invention also includes a tubular body in a cooling bath with a complete device for carrying out such a method of immersing the body and correspondingly intenrens. Such processes are used and a single cooling effect can be achieved. The method for directions among other things in the production of io solution of this problem is characterized in connection hoses and cable sheaths made of thermoplastic 'fertilizer with the aforementioned process steps plastic by extrusion with the invention in that the inclination of the subsequent cooling. In the case of the Kabelummante- liquid level through 'the mirror slope of the treatment is the z. B. is generated from a plurality of liquid flow in a cooling bath, wires existing cable core during extrusion such as 15 whereby the tubular body is guided essentially horibei the subsequent cooling within the zontal and progressively under the liquid still warm plastic jacket. is immersed. That way lets

Methods and devices for cooling are known to achieve an extruded, uniformly increasing cooling and solidification or injection-molded plastic hoses that leave an extruder with the increasing pressure load (German ao generation of a hose or the like, so that Auslegeschrift 1 124 673, ) in which the still warm, gradually increasing pressure load is always with the and therefore more or less plastic hose in each case reached strength of the hose in one over a through-hole adjoining the extruder and inadmissible deformations do not run directly into a cooling bath. Who can enter.

The point where the liquid enters the liquid is greater than that. To carry out the process, it is advantageous to use a depth below the liquid level, ie in the case of a device which has a two-area vessel for receiving the liquid smoke Hose interior has considerably higher speed and is characterized by the fact that the liquid pressure. In some cases, the inward deformation of the hose wall 30, which results in a drive device for the two containers of the vessel, is harmful to the patient's progression towards the horizontal. However, this is often not the case with tubular bodies, which are immersed in the inclined liquid level and are followed by comparatively thin-walled tubular bodies. Such a device 'cheri to and in particular not when extruding allows a thermoplastic cable jacket in particular in an advantageous manner to carry out the method according to the invention in the cable core, which consists of a number of individually isolated continuous operation on one of an extruder wires. The compression of the freshly coming hose, cable or the like.
For the above and the other claimed more or less intensive welding with the furnishing features, protection is only sought in connection with the method according to the invention, often also made of thermoplastic material,
standing core insulation or to a fusing 40. The invention is further refined on the basis of the embodiment shown in the embodiment of the core insulation, that is to say, in relation to an undesired drawing, of reducing the relative mobility between the sheath. Herein shows

and cores, which increases the flexibility of the cable. F i g. 1 is a plan view of part of a cooling unit

is impaired, or to an impairment of the direction,

Insulating effect. 45 Fig. 2A is a longitudinal section along the center line of FIG

The same applies to other known cooling devices according to FIG. 1,

process and cooling devices, as shown in FIG. 2B for a schematically indicated reel "Kunststoffe" magazine, 1955, issue 10, p. 486 to use in the device according to FIG. 1 and 490, are known. It is true that the extruded FIG. 3 a sheathed cable as an application hose or tube when passing through each other - object of the method.

the following container filled with cooling liquid. The illustrated embodiment relates

Pressure gradient generated, meanwhile, the entry takes place on the production of a cable 11 with a plurality

of the still warm and plastic hose always has cores 12, each of which has an insulation 13

at a distance below the liquid level, ie point, and with a jacket 14 as an extruded,

in the area of comparatively high fluid pressure. 55 tubular! Body. The core insulation and the

Furthermore, from British patent specification 822 515 jacket can consist in the usual way of the same a device for the further treatment of freshly thermoplastic material,
extruded plastic hoses are known in which the cable 11 is each cut to a certain length by means of a reel according to FIG. 2B with respect to FIG. 1 and 2A are drawn from the left to the hose into a treatment vessel or storage container on the right through an extruder 17, in which the metal tube of the appropriate length provided for the container is to be bundled and already brought together with its insulation 13. The introduction of the tubular veins 12 are covered with the jacket 14 , ches in the pipe is here with the help of a in the pipe The jacketed cable then runs through a cooling flow of liquid compared to the direction 18 with a vessel for receiving hose diameter smaller depth performed. 65 coolant, ζ. Β. Cooling water.
The hose floats on the stream and the cooling device 18 comprises a long container 19 which is stretched into the pipe and filled with cooling water 21 without the risk of damage. A significant cooling effect compared to that with a certain horizontal abstar.d from the exit

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of the extruder 17 is arranged. The cooling device or fusion with the insulation 13. Also has a second container 22, which is provided between. ^: -r the first container 19 and the extruder 17 are arranged- 'The cable 11 passes through a transition opening is net. The cooling water flows from the first container 19 between the containers 22 and 19 and leaves the latter to the left according to FIGS. Loss of cooling water through the second container 22 and finally into a collecting. Last-mentioned opening is excluded except for a minor container 23. The cable 11 thus runs through its leakage water quantity caused by the pumping action of the running cable from the extruder 17 to the drive device 16 , which the latter first reaches the cooling water in the container 22 and then the- io in a collecting pipe 32. On the opposite that, z. B. a reel, in the container 19. End of the container 19, the cooling water flows freely

In the extruder 7 the plastic mass of the container 22 'passes through the transition opening

The jacket 14 in the warm and molten state consists of a base 33 and side walls 34

on the bundle of cores 12 with their insulation 13. and is at its right end according to FIG. 1 and 2 A

When leaving the extruder, the jacket is therefore 15 pivotable within the end section of the container 19.

sensitive to mechanical influences, fastened to the bar. The right end of the container 22 engages

thus to damage the jacket and also the one in the left end of the container 19; that the

Can lead to core insulation. One on the jacket side walls 34 of the former to the corresponding

14 force acting radially from the outside. the sidewalls 29 of the latter-may be slidable, however

Mass of the jacket z. B. in firm connection with the ao sealingly. :: ^{i ■}

Isolations. 13 bring and an adhesion of the latter The bottom 33 of the container 22 lies on the over,

on the inside of the jacket after cooling, the passage point between the two containers is higher than that

cause. Furthermore, the trough mass of the man bottom 28 of the container 19 inclines, whereby the intermediate space

tel's to melt the insulation 13 or is closed by a wall section 36.-The latter

to merge with neighboring insulation. Ab- as ensures a certain back pressure of the flowing

From this point of view, there is of course the risk of cooling water and thus of an increased level star

the damage to the jacket itself from the outside as well as hydrostatic pressure in the cooling water on the

Scraping, cutting or changing shape. Transfer point from container 19 to container 22. If

On the other hand, it has been found that the jacket after a slight leakage water leakage, but which is generally

cooling and solidification against mechanical 30 is permissible, should be avoided, so can

niche effects is very resistant and between the side walls 29 and 34 and between

There is hardly any risk of damage. the bottom 28 and the lower edge of the Wahdab-

The sheathed cable 11 passes through which suitable seals are attached against the cut 36, the horizontal axis of the cable at an angle A. The pivotable fastening of the container 22 is (FIG. 2A) slightly inclined mirror 24 in the cooling 35 according to FIG G. 2A e.g. B. by juxtaposed water 21 within the container 22. As a result of the approaches 37 and 38 on the underside of the bottom 33 open container, the cable enters the cooling water at or on a vertical transverse wall 39 of the collecting atmospheric pressure. The inclined cooling water tank 23 is made, whereby a continuous mirror 24 extends essentially over the bolts 41 engages in corresponding bearing bores, the entire length of the tank 22, whereby the jacketed * o The left end of the tank 22 is supported gradually progressively over cables immersed and reaches an increasing hydrostatic pressure under punch 42 against the bottom 43 of the collecting container. 23 from. A row of holes 47 is arranged in each of the punches 42. The angle of inclination A of the cooling water level is arranged opposite, so that the height of the left end of the container above the cable axis and thus the increase converter 22 with the aid of the ratio of the hydrostatic pressure in the side walls 34 Cable 45 fenden bolt 46 can be adjusted. In general, taking into account the running speed, the left end of the container22 is set somewhat for the cable and thus the cooling or lowering than the right end, so that the cooling and solidification speed of the jacket can flow through the water with little back pressure In this way, the already mentioned pressure of the cooling water does not result in an intimate level 24 of the cooling water as well as the contact between the insulation 13 and the mass-speaking decrease in the hydrostatic pressure of the jacket leads to the longitudinal direction of the container 22 through sufficient cooling. The bottom 33 of the and solidification protection against sticking and the latter is reached at the left end with a downward melting between these cable components curvature to lower the exiting coolant. 55 water flow provided, so that despite the

When passing through the container 19, the cable 11 becomes a certain low height of the end wall 44 supported by suitable rollers 26, which are stored in brackets 27 of the collecting container 23, an overshooting of the cooling storage and thereby avoided at the bottom 28 of the container water.

are consolidated. The section of the cable between the outlet of the extruder 17 and the outlet of the extruder and the first roller 26 in the first roller 26, the cable 11 runs freely as mentioned.Container 19 is freely suspended and therefore hangs without contact and consequently bends under its with any fixed parts of the cooling device, dead weight by a certain amount, which could cause damage. The Ab- With the help of the explained device for height adjustment. stand D (Fig. 2A) between the first contact position of the left end of the container 22, the point of the cable with the cooling water and the first 65 slope of the bottom 33 and thus the slope roller 26 is dimensioned such that at the point of Angle A of the mirror 24 adjusted accordingly, the latter sufficient cooling and solidification. The indicated in Fig. 2A setting of the jacket and thus security against damage container 22 corresponds, for. B. a lighter cable,

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while for heavier cables a lowering of the cable and the critical distance D from the entrance

Container is required to support contact between the cable in the cooling water up to the first-

Avoid cables and container bottom. 'the roller 26, d. H. the length of the effective cooling

The height adjustment for the. Cable-described range, are the rate of cooling of the inlet end of the container 22 is particularly advantageous, 5 cable sheath during the passage within the cooling If lighter cables with higher speed water-dependent, with the angle A with the Abals for heavier cables treated should be, the cooling speed increases, while the decrease, as is usual in extruder technology for cable production D, with increasing cooling speed. For this purpose, FIG. 2A that one thing is decreasing. The cooling rate of the lighter and consequently less sagging io cable jacket is influenced by various factors, e.g. B. cable at a lower height setting of the left of the cable speed, the temperature of the container end corresponding to a heavier of the cable jacket when entering the cooling water, of cable, ie at a steep, inclined mirror 24, at one of the cooling water temperature, of the material of the cable in comparison to the heavy cable higher body and the cable size and thickness would enter the cooling water level. This means that 15 depends on the cable jacket. Furthermore, in the case of the waste heat, a reduction in the effective running distance is the mood of the two critical variables of the different melting points of the cable ties which may be different under the cable in the cooling water, ie the distance D. Furthermore, due to the larger Nei- mantels and the core insulation, the angle of inclination Λ of the cooling water level would have a stronger If z. B. on a wire bundle with polyvinyl increase in hydrostatic pressure on the lighter ao plastic existing wire insulation a sheath and faster running cables should be applied from the same material when immersed. This can result in an impermissible contact pressure with a cooling water temperature in the between the cable jacket and the core insulation in front of the first container 19 of about 21 ^° C. with sufficient cooling and solidification of the latter temperature of the cable jacket in the cooling water of about. The height adjustment, however, allows a 25 177 ⁰ C for a comparatively thin cable with an exact adjustment of the mirror inclination and thus the outer jacket diameter of about 1 cm and an effective cooling section as well as the outer jacket thickness of 0.875 cm at a running speed of the hydrostatic pressure depending on the cable speed of 65 m / min, the occasional cable speed is particularly favorable and the cable penetration results with an angle A = 3 ° in the case of a slope. _. 30 stood D = 3 m, for a comparatively strong cable

On the other hand, it is possible under certain circumstances to use the height adjustment range for the cable entry end with an outer jacket diameter of about 1 inch and a jacket thickness of 0.75 reduce,, 4 = 9 ° and a distance /) in the order of magnitude, possibly even to the value zero, by namely 35 of 2.4 m, provided that the bottom 33 of this container runs at a convex downward speed of 30 m / min when lowering the curved shape is obtained, which essentially corresponds to the cable entry end of the container 22 in such a way that the hanging shape and the path of the heaviest contact between the cable and the floor 33 does not come into consideration cables. One of the- occurred. The other conditions were in the case of the last-type construction, which also requires the lower edges of the side walls 34 that are correspondingly curved 40 compared to the treatment, but are unchanged for the lighter cable. Both exemplary ühgegenüber the version with height adjustment of approximately examples led to a cooling of the wire to wire entry end especially complex and in the mantels to about 149 ⁰ C during the lead time production difficult. between entry point and first roller 26. At the

The cooling water with the temperature mentioned 45 is such a solidification to the first container 19 predetermined temperature over several inlet of the cable jacket that the hydrostatic tubes 48 from a reservoir, not shown, pressure in the first container 19 and contact with fed. Each of the inlet tubes 48 is with one of the first rollers 26 no damage to the cable regulator valve 49, so that the result of the cable jacket or the core insulation is more. exit and through the transition opening to the loading 50 When preparing the treatment facility Container 22 outflowing amount of water is compensated for the extrusion and cooling of a cable and the cooling water level on one for the safe loading of the cable entry end of the container initially by means cover of the cable sufficient height held the device described on the stamps 42 on can be. adjusted to such a height that the sagging

The side walls 51 of the collecting container 23 are cut out in the cable section between the exit of the extruder and the left end section according to FIG. Preferably, the setting of the cable entry end and the height adjustment of the container are selected as high as possible in order to make the container 22 easily accessible. From the angle A of the cooling water level and thus the bottom 43 of the collecting tank, a line 60 leads to the hydrostatic pressure taking ratio to the 52 z. B. via a pump, not shown, and a cable when immersed in the cooling water on a cooler or heat exchanger back to Vorratsbe- minimum and at the same time the distance D to a container for cooling water, from where the circuit to bring about maximum. Furthermore, the inflow to the inlet pipes 48 is closed. The amount of leakage water discharged via the cooling water via the inlet pipes 48 by means of the Regufangrohr32 is fed back into 65 discharge valves 49 according to the outflow via the downstream circuit. interconnected container as well as according to the

The critical angle of inclination A of the cooling water leakage at the cable outlet to a sufficient height

mirror set in the container 22 with respect to the passing of the cooling water level in the container 19.

Then the cable head leaving the extruder is for the first time through the cooling device to Reel out. The described continuous flow then begins with cooling and solidification of the cable jacket.

Claims (9)

Patent claims: 1. A method for cooling an extruded, tubular body, in particular a one Strand encasing sheath, in which the tubular body with a liquid flow in Is brought into contact with the liquid level inclined with respect to ■ the horizontal, characterized in that the inclination of the liquid level is determined by the slope of the level the liquid flow is generated in a cooling bath, the tubular body in the is guided essentially horizontally and progressively submerged below the liquid level. 2. The method according to claim 1, characterized in that the inclined liquid level from its intersection with the substantially horizontal trajectory of the tubular Body extends over a comparatively large distance in the direction of travel of the tubular body. 3. The method according to claim 1 or 2, characterized in that the mass flow of the liquid in the area of the entry point of the tubular body into the liquid in one direction to the direction of travel of the tubular body opposite flow direction in coordination with the Inclination of the liquid level is such that the pumping action of the running tubular Body is balanced on the fluid. 4. The method according to any one of the preceding claims, characterized in that the Angle of inclination of the liquid level with respect to the running tubular body about 3 to 9 °. 5. The method according to any one of the preceding claims, characterized in that the tubular Body within the liquid at a distance from its entry point into the cooling bath arranged point is supported and that the portion of the tubular body between leaving a heat treatment section and being supported within the liquid is led hanging. 6. Device for performing the method according to one of claims 1 to 5, with a vessel comprising two containers for receiving the liquid, characterized in that that the two containers (19, 22) of the vessel a drive device (16) for the progressing in the tubular body immersed in the liquid level (24) inclined to the horizontal (14) is connected downstream. 7. Device according to claim 6, characterized in that the outlet of the tubular The end of the vessel associated with the body (14) is essentially closed, that the other end of the vessel is essentially open to the freely flowing liquid and that inlet pipes (48) are provided for the continuous supply of cooling liquid into the vessel are. 8. Device according to claim 6 or 7, characterized in that the angle of inclination (Λ) of the The level (24) of the cooling liquid (21) with respect to the tubular body (14) is approximately 3 to 9 °. 9. Device according to one of claims 6 to 8, characterized in that the bottom surface of the an inclined liquid level inducing container (22) with respect to the bottom surface of the other container (19) has a higher position. 1 sheet of drawings