FIELD OF THE INVENTION The invention relates to an arrangement for keeping a pipe unfrozen which comprises an insulation layer provided with a heat-conductive strip.

The invention also relates to a method of manufacturing an ar- rangement for keeping a pipe unfrozen, the method comprising guiding insula- tion and a heat-conductive strip into each other.

The invention further relates to an apparatus for manufacturing an arrangement for keeping a pipe unfrozen, the apparatus including means for feeding insulation and means for feeding a heat-conductive strip inside the in- sulation.

BACKGROUND OF THE INVENTION It is conventional to arrange a layer of thermal insulation around a pipe to be kept unfrozen, such as a water pipe. External insulation of the pipe does not, however, always sufficiently guarantee that the pipe remains unfro- zen. Solutions for defreezing a pipe or for keeping it unfrozen also exist where a thermal cable is mounted inside the insulation layer. The cable heats the pipe, thus keeping it unfrozen or defreezing it. However, it is rather difficult to implement installation thermal cables inside insulation material as a retrofit, for example. In particular, it is difficult to achieve watertight solutions. Solutions also exist where a thermal cable is mounted on the pipe surface and an alu- minium strip is arranged on top of the cable to enhance heat transfer from the cable to the pipe. An insulation layer is arranged outside these and an outer sheath outside the insulation layer. The price of such a solution is, however, rather high, especially if the pipe is relatively long. It is rather difficult to imple- ment solution of this kind as a retrofit because a pipe trench is required. Fur- thermore, if one does not want to provide the whole length of the pipe with the arrangement for keeping the pipe unfrozen, a pipe connection has to be pro- vided between the non-insulated pipe and the insulated pipe to be added.

BRIEF DESCRIPTION OF THE INVENTION The object of the invention is to provide an improved arrangement for keeping a pipe unfrozen and a method and an apparatus for the manufac- ture thereof.

The arrangement for keeping a pipe unfrozen according to the in- vention is characterized in that the heat-conductive strip is attached to the in- ner surface of the insulation layer in such a way that there is an assembly space between the heat-conductive strip and the insulation layer.

The method of the invention is characterized by attaching the edges of the heat-conductive strip to the inner surface of the insulation in such a way that an assembly space is formed between the heat-conductive strip and the insulation.

The apparatus of the invention is characterized in that the apparatus includes means for attaching the edges of the heat-conductive strip to the inner surface of insulation in such a way that an assembly space is formed between the heat-conductive strip and the insulation.

The basic idea of the invention is that the arrangement for keeping a pipe unfrozen includes an insulation layer which is provided with a heat- conductive strip. The heat-conductive strip is attached inside the insulation layer in such a way that an assembly space is formed between the heat- conductive strip and the insulation layer for a thermal cable, for example. More preferably, the heat-conductive strip is attached inside the insulation layer by heat. There is preferably also an outer sheath outside the insulation layer, and the arrangement for keeping a pipe unfrozen includes end covers so that a watertight solution can be achieved.

An advantage of the invention is that the arrangement for keeping a pipe unfrozen is easy to install so that it is mounted around the pipe to be kept unfrozen only at necessary points. Retrofitting of the arrangement for keeping a pipe unfrozen according to the invention is also simple and easy. It is very easy to make the arrangement for keeping a pipe unfrozen equipped with an outer layer and an end cover completely watertight.

In this specification, the term'arrangement for keeping a pipe unfro- zen'refers to a solution where one tries to keep a pipe unfrozen, i. e. tries to prevent the pipe from freezing and/or tries to defrost a frozen pipe.

BRIEF DESCRIPTION OF DRAWINGS The invention will be described in greater detail in the accompany- ing drawings, in which Figure 1 is a schematic cross sectional view of an arrangement for keeping a pipe unfrozen seen from one end;

Figure 2 schematically illustrates an apparatus for manufacturing the arrangement for keeping a pipe unfrozen, and Figure 3 schematically illustrates the arrangement for keeping a pipe unfrozen installed in a water pipe which enters a building.

DETAILED DESCRIPTION OF THE INVENTION Figure 1 shows an arrangement for keeping a pipe unfrozen. In the middle of Figure 1, there is the pipe 1 to be kept unfrozen. The pipe 1 may be, for example, a water pipe or a pressure sewage pipe or a pipe for some other purpose where flowing fluid should be kept unfrozen. The material of the pipe 1 may be polyethylene PE or cross-linked polyethylene PEX, for instance. The pipe 1 can also be manufactured from some other plastic material or from metal or another suitable material.

Outside the pipe 1, there is insulation 2 around the pipe 1, and the insulation thus forms an insulation layer. The insulation 2 is most preferably cross-linked closed-cell polyethylene foam. The insulation 2 may also consist of one or more layers. Further, the insulation may be made of some other ma- terial, such as foamed polypropylene or polyurethane.

A heat-conductive strip 3 is attached inside the insulation layer in such a way that there is an assembly space 4 between the heat-conductive strip 3 and the insulation layer 2. In the assembly space 4, there is a thermal cable 5. The thermal cable 5 heats the pipe 1 and the fluid flowing therein. The heat-conductive strip 3 enhances heat transfer from the thermal cable 5 to the pipe 1. The thermal cable 5 is in contact with the heat-conductive strip 3, and thanks to its good thermal conductivity, the heat-conductive strip 3 enhances the influence of the heat of the thermal cable 5 on keeping the pipe 1 unfrozen.

The heat-conductive strip may be made of aluminium foil or aluminium foil coated with polyethylene PE, for example. The thickness of the aluminium foil is approximately 0.1 mm and its width approximately 60 mm, for instance. The heat-conductive strip may also be made of suitable heat-conductive material other than aluminium.

Outside the insulation 2, there is an outer sheath 6. The outer sheath 6 is most preferably made of polyethylene PE. Furthermore, the outer sheath 6 is most preferably corrugated, in which case the ring stiffness of the arrangement is rather good, for example 8-12 KN/m2. However, thanks to cor- rugation and softness of the insulation 2, the arrangement is bendable. Thus

the arrangement can be wound on a reel e. g. for storage and transportation and reeled out in connection with installation. The diameter of the pipe 1 may vary between 25 and 110 mm, in which case the outer diameter of the outer sheath 6 may vary between 60 and 200 mm, for instance. The thickness of the insulation layer may vary between 10 and 40 mm, for example.

Figure 2 illustrates an apparatus for manufacturing an arrangement for keeping a pipe unfrozen. The insulation 2 is prefabricated, board-shaped insulation which is wound on a reel 7. For the sake of clarity, Figure 2 does not illustrate means for supporting and rotating the reel 7. Correspondingly, the thermal cable 5 is on reel 8 and the heat-conductive strip 3 on reel 9. The means for supporting and rotating the reels 8 and 9 are not shown in Figure 2 for the sake of clarity. The thermal cable 5 is guided against the inner surface of the insulating board, i. e. against the surface which forms the inner surface of the insulation layer when the insulation board is wrapped into a tubular form.

The heat-conductive strip 3 is guided onto top of the thermal cable 5.

The apparatus further comprises nozzles 10 for heating the edges of the heat-conductive strip 3 and/or the insulation 2 at the point to which the heat-conductive strip 3 should attach. The nozzles 10 are shaped so as to al- low them to direct thermal effect at the desired point very accurately. The ap- paratus may also comprise a protective plate 11, which protects the thermal cable 5 against extensive heating of the cable. The protective plate 11 may be, for example, a metal plate which prevents extensive heating of the thermal ca- ble 5. The heated heat-conductive strip 3 and the insulation 2 are pressed against each other by means of a rotating roll 12. The roll 12 is made of polytetrafluoroethylene PTFE, for instance. The roll 12 is shaped to press the edges of the heat-conductive strip 3 against the insulation 2 but the roll 12 is also provided with a groove so as to prevent the roll 12 from pressing the mid- dle section of the heat-conductive strip 3 against the insulation 2. Thanks to this structure and the thermal cable 5, an assembly space 4 which the thermal cable 5 occupies is formed between the heat-conductive strip 3 and the insula- tion 2. The middle section of the heat-conductive strip 3 is not heated, either, in which case the thermal cable 5 remains covered by the unheated section of the strip in the middle of the strip 3, thus forming a free assembly space 4 be- tween the insulation 2 and the strip 3. Instead of the roll 12 provided with a groove, it is feasible to use two separate rolls. In that case each roll presses different sides or edges of the strip 3 against the insulation 2.

When the heat-conductive strip is made of aluminium foil coated with polyethylene PE or other plastic material, the strip 3 is attached to the in- sulation 2 most preferably by blowing hot air through the nozzles 10. If the heat-conductive strip 3 is made of uncoated aluminium foil, a flame can be di- rected at the attachment point by the nozzles 10, in which case the attachment occurs by flame lamination. Another feasible attachment method is to laminate the aluminium foil to the insulation by means of a heated plate like a soldering hammer or another similar piece.

The apparatus further includes a wrapping device 13 for wrapping prefabricated, board-shaped insulation 2 into a tubular form. The sides of the board-shaped insulation 2 are joined by a welding device 14. A joint formed between the sides of the board-shaped insulation 2 which are against each other is fused with hot air, for example, so as to provide the insulation 2 with a tubular form. Instead of utilizing hot air, the welding device 14 may fuse the joint by another method known per se. Instead of the welding device 14, the sides of the board-shaped insulation can be joined by a gluing device, for ex- ample.

The insulation wrapped into a tubular form is guided through a noz- zle 16 of an extruder 15. The extruder 15 and the nozzle 16 extrude a plastic layer outside the insulation 2. A corrugated outer sheath 6 is formed from the plastic layer in a corrugator 17. The corrugator 17 is provided with two moving chill moulds 18 in a manner known per se. The structure and function of the extruder 15, nozzle 16 and corrugator 17 are not described more closely here since they are completely known to a person skilled in the art.

For the sake of clarity, Figure 2 does not show guiding devices or support structures that are needed to feed the insulation 2, thermal cable 5 and heat-conductive strip 3.

The thermal cable 5 can be fed continuously from the reel 8, in which case the arrangement for keeping a pipe unfrozen, inside of which there is a thermal cable 5, is produced continuously. The thermal cable 5 may also be fixed so that an assembly space 4 is formed when the heat-conductive strip 3 is pressed against the insulation 2 but when the strip 3 and the insulation 2 move forward in the apparatus, no cable is fed into the assembly space 4 but it remains empty. Instead of the thermal cable 5, the assembly space 4 can natu- rally be formed by another band-shaped or rod-shaped object or by means with another appropriate shape. Furthermore, in the solution of Figure 2, a pipe

is not fed inside the arrangement for keeping a pipe unfrozen but an arrange- ment is formed which is slipped around the pipe after the manufacture. It is also feasible to manufacture a product where one or more pipes are continu- ously fed inside the insulation 2 during the manufacture.

If the arrangement for keeping a pipe unfrozen has been provided with an empty assembly space 4, the thermal cable 5 can be afterwards slipped inside the arrangement for keeping a pipe unfrozen which has been cut to size, for instance. The arrangement for keeping a pipe unfrozen can even be installed first, and a thermal cable 5 is added later, if necessary.

Figure 3 illustrates an arrangement for keeping a pipe unfrozen in- stalled in a water pipe 1 entering a building 21. The water pipe 1 is placed deep enough below the ground surface, i. e. below the frost limit, in which case the water pipe 1 does not in practice need to be insulated at all. At points where the water pipe 1 enters the building 21, it has to be installed closer to the ground surface, and thus there is a risk that the pipe 1 will freeze at the points where it enters the building. Freezing can be prevented by the solution shown in Figure 3. The installation starts by first installing the pipe 1 cut to size. After this, the first end cover 19a is slipped from the end of the pipe 1.

Then the rest of the arrangement for keeping a pipe unfrozen is slipped around the pipe 1, and the second end cover 19b is installed last. The end covers 19a and 19b are sealed to the ends of the arrangement for keeping a pipe unfrozen on top of the outer sheath 6. The structure, material and installation of the end covers is not discussed in greater detail here because these issues are familiar to a person skilled in the art. Thanks to the end covers 19a and 19b and the outer sheath 6, the arrangement for keeping a pipe unfrozen can be made wa- tertight. A connector is arranged at an end of the thermal cable 5. At its sim- plest, the connector 20 is a plug which can be directly plugged into a socket of a 230 V electric network in the building 21.

It is obvious to a person skilled in the art that as technology ad- vances, the inventive concept can be implemented in various ways. The inven- tion and its embodiments are thus not restricted to the examples described above but they may vary within the scope of the claims. Thus the insulation 2 does not need to be prefabricated in a board shape but it may be prefabricated in a tubular form. Furthermore, the arrangement for keeping a pipe unfrozen may be provided with a split in the longitudinal direction by means of which the arrangement can be installed around the pipe 1 in the horizontal direction. In

that case it is unnecessary to slip the arrangement for keeping a pipe unfrozen around the pipe from its one end in the longitudinal direction. In addition, the arrangement for keeping a pipe unfrozen may be arranged either around one pipe 1 as shown in Figure 1 or around more than one pipe. Furthermore, the length of the arrangement for keeping a pipe unfrozen may be tens or hun- dreds of metres, in which case it is stored on a reel and cut as required. On the other hand, it is feasible to manufacture units which are cut to size, e. g. a length of few metres, and which include a suitably sized thermal cable 5 and all necessary equipment, such as end covers and installation means.