NO175625B - - Google Patents

Description

The present invention relates to a method for continuous thermal insulation of rigid conduit pipes, as stated in the preamble to the subsequent claim 1. Conduit pipes produced by such a method are particularly intended for the transfer of liquid or gaseous, heated or cooled media

There are previously known methods for both continuous and discontinuous production of heat-insulated conduit pipes with a protective outer jacket made of plastic. Examples include DE 1 704 748, DE 1 266 485, DE 3 307 865, DE 2 803 708 and AT 377 227.

In several of the various known, continuous manufacturing methods, the conduit pipe, which is provided with spacers, is introduced together with a plastic foil tube that serves as a protective jacket, through a stationary form tube, whereby the edges of the plastic strip are joined and welded together with the plastic foil tube immediately before the introduction into the stationary form tube. The plastic mixture, which is to be foamed, is usually applied to the plastic film tape just before the joining and welding of the overlapping edges of the plastic film tape which is formed into a plastic film tube. During the passage through the stationary form tube, the foaming of the ring channel takes place between the lead tube and the snake-shaped protective outer jacket. In this method, the plastic foil hose can optionally be replaced by an aluminum foil which is coated on both sides with copolymers and where the protective jacket is extruded using an extruder (DE 3 3 07 865) after the foamed conduit has passed through the stationary form tube.

These continuous methods have, however, in practice proven unsuitable for the production of conduit pipes with larger diameters, because the frictional forces that arise between the outer jacket and the stationary mold tube due to the occurring foam pressure become too great for the passage through the stationary mold tube to take place quickly, even if a lubricant is also used between the outer casing and the stationary form tube. In contrast to the continuous method, a discontinuous method is therefore used in practice, particularly for conduits with lengths of 6-12 meters and diameters of 20-60 mm, whereby the conduit is first supplied with foam-permeable spacers at certain intervals, and covered with a relatively thick plastic hose. The construction thus produced is then successively foamed in an inclined position. In this method, the thickness of the plastic hose is adjusted according to the resulting foam pressure, as the hose, in addition to forming the outer jacket, must also serve as a "form". The plastic hose must therefore be so powerfully dimensioned that it can absorb the resulting foam pressure. Apart from the fact that this method has the disadvantage that it is necessary to use a thick plastic hose, it is also a fact that no regular foam is formed during the inclined position foaming and that the foam also has a relatively high density. The discontinuous production method is also not economically advantageous.

The double-former block belt conveyor, which is used in connection with the invention, is known in and of itself and is used, for example, for the continuous production of longitudinally split foam plastic insulation pipes, according to DE 1 266 485, or for the continuous production of double-foamed and collapsible pipe half-shells, as known from DE 2 503 425, which are interconnected in a hinge-like manner through an outer foil.

In the continuous production of the longitudinally split foam plastic insulation tubes, according to DE 1 266 485, particular difficulties have been shown to arise in connection with the retention of the core which extends the full length of the mold channel which is formed by the two movable mold block chains and which is necessary for creation of the inner channel of the foam plastic insulation pipe. The pressure, which is developed by the foam in the mold channel, has proven to be so great that the core cannot be kept centered throughout its entire length, even if it is firmly clamped at both ends. To prevent such deviations, a load-bearing support plate is therefore arranged along the entire core which extends radially into the mold channel between the mutually opposite mold blocks.

The same conditions, regarding the straightening of the core, also apply to another, known plant where a stationary mandrel element is used as the inner core, which is attached only at the plant's entrance end and extends freely into a stationary or rotating outer shape. In this case too, the mandrel element, which is only clamped on one side, does not have sufficient stability to absorb, without lateral deviation, the pressures that occur during the foaming. Reference is made in this connection to the above-mentioned DE 2 503 425, column 3, line 49 et seq. Due to problems with the above-mentioned core deviation, it is therefore, in connection with another, known facility et al. DE 2 165 584, proposed to control the lateral deviation of the mandrel element by means of a laser beam and to correct the lateral direction by using regulation and control elements. With such an auxiliary device, however, a perfect lateral alignment of the permanent inner core (mandrel element) will only be achieved with difficulty, apart from the fact that the entire system will be very complicated and highly susceptible to operational disturbances.

The main purpose of the invention is therefore to arrive at a method of the kind indicated at the outset where it

a double-former-block belt conveyor is used, but without the above-mentioned difficulties in connection with the retention of the core.

According to the invention, this has been achieved with the new and distinctive features which are specified in the characterizing part of the subsequent claim 1. Advantageous embodiments of the invention are specified in the other subsequent claims.

In the method according to the invention, the conduit pipes are thus maintained centered in the form by being held concentrically positioned by the already load-bearing foam plastic.

Admittedly, it is known from DE 2 803 708 that the load-bearing capacity of the foam material is of significant importance to ensure the concentric location of the inner tube. According to the latter publication, however, it is only about thin-walled tubes that are refoamed by extrusion through an annular nozzle, as the foam immediately after flowing out of the nozzle surrounds the nozzle in an annular shape and the thin-walled tube "swims" in the not yet hardened thermoplastic foam, whereby it is fixed in position, as which is known in the preamble to current claim 1 in the present application. The plastic tubes inserted according to DE 2 803 708 are actually so thin that it is stated in the last paragraph in column 4 that no deformation takes place during re-spraying. Such thin-walled pipes which are to be refoamed cannot be compared to the very large pipes to which the present invention is applied, and which cannot be supported by the extruded plastic material which is still in a molten state. According to the present invention, with the help of the polyurethane foam plastic system, a polyurethane hard foam plastic is formed which must be sufficiently hardened when the centering effect of the pipe feeder and holder device is no longer provided, i.e. when the pipe would otherwise bend down.

The method according to the invention thus makes it possible to thermally insulate conduits, also of larger diameters, continuously and in an economically reasonable manner while simultaneously saving material for the outer jacket and producing a regular foam of low density in the heat-insulating layer.

On the basis of the previous experiences with. double-former-block-belt conveyors in connection with the production of longitudinally split foam plastic insulation pipes, it must be considered very surprising that with the method according to the invention it is possible to produce conduit pipes which are insulated with foam plastic, and where the conduit pipes, even with large diameters, are concentrically fixed in position in the foam.

The continuous method made possible by the invention allows a continuous refoaming of the lead pipes, which entails the advantage that the foam plastic sheath, at a low bulk density, has a homogeneous cell pattern without bubbles along its entire length whereby, in addition to a uniform, mechanical firmness, it also better lambda values are achieved.

By means of the extruder with associated vacuum calibration device, which is connected behind the double-former-block belt conveyor, it is also possible to manufacture the foamed plastic protective jacket with correct shape, with high density and

smooth outer skin in an economically reasonable way. By the procedure,

according to the invention, the plastic protective sheath can also be significantly thinner than with the discontinuous method described at the outset, as the pressure that occurs during the formation of the heat-insulating foam plastic layer no longer has to be absorbed by the plastic sheath. In the method according to the invention, the functions of the plastic jacket will consequently be limited to diffusion density and protection against damage during transport. The foamed protective sheath reduces weight and cost, and increases flexibility.

As the plant, according to the invention, is constructed in such a way that the conduit pipes will automatically be located concentrically with the outer jacket, i.e. in the middle position, all spacers or centering holders, which according to the state of the art have been necessary up to now, can also be dispensed with. Thereby, the further advantage is achieved that the large number of cold bridges is eliminated, whereby the heat-insulated conduit, which is produced in accordance with the invention, will be further significantly improved and cheaper.

The method, according to the invention, is suitable for all conduits, for example made of copper, steel or plastic, which are to be thermally insulated. If it is a question of copper or plastic pipes of small diameters, e.g. 2 2 mm, these, after being bent back in a straight line, can be advanced practically endlessly to the double-former block belt conveyor from the drum where they have been stored in delivery lengths of 50 m or more, and after foaming and application of the plastic jacket, rewound on a drum.

Plastic pipes of larger diameters are most advantageously produced by extrusion immediately before the device used in accordance with the invention, whereby the handling of the pipes is omitted. After leaving said device, the lead pipes, which can no longer be wound on a drum, are cut into heat-insulated pipe sections of the desired length.

Rigid pipes, for example steel pipes or other metal pipes, are preferably used for lengths of 12 to 18 m which, just before the introduction into the device used in accordance with the invention, are joined with special plastic sleeves to form an "endless string" which then, likewise practically " end-loose" is refoamed and an outer coat applied during a continuous process. After being provided with the outer jacket, the pipes are separated again with the help of special saws in the zone at the sleeves, i.e. the pipe connection sections. These connecting sections are constructed in such a way that when the sections are removed when laying out the heat-insulated conduit pipes, the pipe ends are exposed, without foam plastic insulation, so that the conduit pipes can then be joined tightly and permanently with ordinary pipe connection sleeves, and then insulated.

In the production of polyurethane foam, it is necessary to use a separating foil which is introduced together with the lead pipe in the double mold block conveyor, so that it is brought into contact with the mold blocks. Thereby, the ring chamber between the separating foil and the conduit is foamed.

Any type of foil, for example paper, plastic or metal, can be used as a separating foil. To achieve a clean separating effect, it is sufficient that paper or plastic foil is used as the separating foil. If, however, additional effects are desired, for example the reflection of heat or the creation of a vapor barrier, a metal foil can advantageously be used, e.g. aluminum foil coated with paper or plastic on one or both sides.

The introduction of the foamable mixture into the ring channel between the conduit and separating foil or form block chains takes place in the usual way, for example as described in the aforementioned DE 3 307 865, by applying the mixture to the separating foil before joining it to the foil hose. The setting of the foamable plastic material, preferably components A and B for the formation of polyurethane foam, takes place so that the foam plastic, already shortly after the snake-shaped separating foil with the applied foamable mixture is introduced into the double-former block belt conveyor, fills the ring channel between the conduit and separating film, while the conduit is held in a concentric position by the already load-bearing foam plastic. The rules of conduct, which are required for this, will be known to the expert, or can be communicated without difficulty.

During the foaming of the conduit pipe, if desired, one or more signaling conductors can be simultaneously foamed in at a distance from the conduit pipe. The signal conductors serve to indicate and locate moisture that has penetrated into the foam plastic layer.

The method, according to the invention, of course also allows the simultaneous foaming of several mutually insulated conduits which are surrounded by a common plastic protective jacket. Two conduits can thereby be advantageously placed in one plastic protective sheath and insulated against each other, so that the cross-sectional shape of such a composite construction is preferably not circular, but oval. This device can, for example, be used as a branch line from the main line to the consumers, as forward and return flows are thereby arranged in one unit, so that the costs in connection with transport and laying can be reduced.

The invention is described in more detail below with reference to the accompanying drawings, in which: Fig. 1 shows a schematic, upper plan view of the core sec

tion in the device, according to the invention.

Fig. 2 shows a schematic cross-section, along the line A-A

in fig. 1, of the former blocks (5a, 5b, 5a', 5b') which form the double former block chains in the belt conveyor system (5). Fig. 3 shows a cross-section of a heat-insulated conduit 7, according to the invention. Fig. 4 shows a section of a pipe connection section 12.

In fig. 1-4 and the subsequent design examples, the reference numbers have the following meaning:

1 Conduit

2 Separation foil supply roll

3 Separating foil

4 Foaming machine

5 Double shaper block belt conveyor 5a, 5b,

5a', 5b' Forming blocks forming the forming block chain 6 Vacuum calibrated extruder

7 Heat-insulated conduit

8 Mold channel which is delimited by the mold blocks 5a, 5b.

9 Stand for controlling the mold block chains

10 Heat-insulating foam plastic layer

11 Foamed plastic protective jacket

12 Pipe connection section

In the schematically shown double-former block chain-belt conveyor 5, according to fig. 1, two mold halves are arranged which are divided longitudinally into individual mold blocks 5a, 5b, 5a', 5b' and which move at the same speed along a straight line. Tightly compressed, the individual mold blocks 5a, 5b form the necessary mold channel, and outside the manufacturing area they are diverted on the guide stand 9 in a known manner as separate mold blocks 5a', 5b' (see Fig. 2) and returned. In adaptation to the respective, desired, diameter of the conduit pipe or the heat-insulating foam plastic sleeves, the former blocks 5a, 5b can be replaced.

The finished, heat-insulated conduit 7 (see Fig. 3) is then wound on a transport drum and transported to the place of use where it is laid out from the drum.

Rigid, non-flexible conduit pipes 1, particularly of large diameters and in lengths of 6-18, preferably 12-18 m, from a supply rack not shown in fig. 1, is advanced by the tube feeder and holder device, also not shown, into the double-former-block belt conveyor 5, together with separating foil 3 which is unwound from a separating foil supply roll 2, whereby the separating foil, before it is introduced into the conveyor 5, is applied with a foamable mixture and is formed into a hose by means of a foaming machine 4. After leaving the double-former-block-belt-conveyor 5, the conduit 1 with the applied foam-plastic coating 10 is passed through an extruder 6 with an associated vacuum calibration device, where the actual Foam plastic protective jacket 11 of polyurethane rigid foam is transferred onto the separating foil 3.

In order to achieve a continuous manufacturing process, the lead pipes 1, which are to be insulated, are joined in series by means of pipe connection sections 12, as shown in fig. 4, and fed as an almost endless string through the double-former-block belt conveyor 5. Outer and inner diameters of the pipe connection sections 12 are adapted to the respective conduit pipe 1 and the desired heat-insulating foam plastic layer 10. After leaving the extruder 6 with the associated vacuum calibration device and after the plastic protective jacket 11 is applied, the pipe connection section 12, which is not visible from the outside, is cut in the middle, across the longitudinal axis, with a guided saw. The heat-insulated conduit pipes 7, which are thus separated again, are conveyed over a storage rack to a packaging or bundling unit. The sheathed pipe connection sections will preferably still be connected to the heat-insulated conduit pipes 7, to be removed just before the pipes are assembled.

However, the heat-insulated conduit pipes 7, which proceed from the extruder's 6 vacuum calibration device, can of course be immediately separated from the pipe connection sections 12, so that these sections 12, which are not sheathed, can be used again after the enclosing separation foil 3 with the plastic protective jacket 11 has been removed. The heat-insulated conduit pipes 7, which are freed from the pipe connection sections 12, can then, for transport to the assembly site, be provided with other protective caps if desired.

The use of the pipe connection sections 12, in accordance with the invention, offers the further advantage that the cable pipe ends, as soon as the pipe connection sections 12 are removed, are exposed for the later necessary, regular and permanent, tight-fitting pipe sleeve connection.

Claims (1)

Method for continuous thermal insulation of rigid conduit pipes (1) with a large diameter, preferably those with a diameter of 20 to 60 mm and lengths of 6 to 18 m, which are interconnected by means of pipe connection sections (12), where the conduit pipes (1) as a almost endless strand is fed continuously coaxially through a tubular cavity formed by a double-former-block belt conveyor (5) under simultaneous plastic refoaming in the axial direction, after which the foamed lead pipe (1) which has left the double-former-block belt conveyor (5) is applied a plastic protective mantle of high density using an optionally cooled, vacuum-calibrated extruder (6) and a ring nozzle, characterized in that a polyurethane-hard foam plastic material is used as a foamable plastic mixture which hardens sufficiently quickly so that it can support the conduit (1) at the latest when this otherwise would break out or hang down due to its own weight.