WO1998035178A1

WO1998035178A1 - Dual tube system, method and tools for the production thereof

Info

Publication number: WO1998035178A1
Application number: PCT/DE1998/000345
Authority: WO
Inventors: Josef Kröner
Original assignee: Kroener Josef
Priority date: 1997-02-11
Filing date: 1998-02-09
Publication date: 1998-08-13
Also published as: EP0960302A1; DE19705073C1; AU6609298A

Abstract

Disclosed is a dual tube system, specially for heating, sanitary, cooling and industrial processing purposes, wherein the dual tubes and the pertaining connector element are all made of a single piece of plastic and consist of a core tube (29), an outer tube (30) and spaced centering rods (25). The dual tube pieces in both the outer tube (30) and the core tube (29) are stepped on the front sides, forming coupling sleeves (23) or connection shanks (24) along the perimeter of said tubes. Said steps correspond to the steps on the other end or on another dual tube so that the dual tubes can be inserted into each other and can be stuck to each ot her, forming smooth junctions arise on both the inside and outside of the walls. The invention also relates to a method for the production of said system and to tools for the implementation thereof.

Description

Double tube system, method and tools for its production

DESCRIPTION

The invention relates to a double-pipe system, in particular for heating, sanitary, refrigeration and process engineering, a method for producing the system and tools for carrying out the method, according to the preamble of claims 1, 13 or 15 and 16.

Heating systems require two-pipe systems that direct the water heated by the boiler to the radiators and back to the boiler. In sanitary engineering, two-pipe systems are required to conduct the hot water heated by the boiler via the main line to the consumers (e.g. shower) and back to the boiler via a secondary or circulation line.

The previously known line systems in heating technology are usually carried out by locally separate pipes, which means corresponding assembly effort. The space requirement of two separate pipes is correspondingly large. The heat radiation surface to the outside, resulting from the total surfaces of the two pipelines, leads to undesirable losses, which must be reduced with an additional considerable amount of insulation measures.

Instead of using two separate pipelines for the main and return or secondary line, it is already known to use a system of double pipes. The hallmark of such double-tube systems is the integration of the main and return lines in a line that consists of a tube and has a hollow jacket. In process engineering, which requires such double pipe systems in order to keep the medium to be transported (for example thermoplastic) flowable by means of trace heating in the outer pipe if this is to be fed through the pipes for further processing.

Such a double-tube system is known from DE 31 05 406 AI, consisting of the double tubes themselves and necessary connecting parts, such as sleeves with centering and sealing device and connecting pieces. The double tubes are each composed of a core tube and a jacket tube, which are kept concentrically at a distance from one another by means of centering rings with radial centering webs pushed onto the core tube, the two tubes remaining axially displaceable relative to one another. The double pipe parts are assembled in the system by core pipe sleeves with centering device. A self-sealing effect is only achieved for the core tubes in that the cylindrical core tube in the conical sleeve e.g. is driven by axial hammer blows. The casing tube is not sufficiently sealed and must be welded in addition. Disadvantages of this known double pipe system are the complicated, relatively time-consuming and therefore costly assembly, but also the complex storage of the many loose parts, such as pipes, sleeves, centering rings.

Finally, from DE 85 33 721.8 Ul a circulation line for a water line for hot domestic water is known, in which a relatively thin circulation line made of plastic, concentrically held by holders not described, is arranged concentrically within a copper pipe. The outer copper pipe connects a water heater with hot water points, such as a tap, with the inner circulation pipe open in front of the Tap or hot water point ends inside the outer copper pipe. In the area of the water generator, the circulation line is led out of the copper pipe, passed through a circulation pump and then flows into the hot water generator. As a result, circulation is always achieved within the copper pipeline, specifically from the outside of the copper pipeline into the plastic circulation line and the hot water generator. Apart from the fact that in this known hot water pipe the jacket pipe is the hot water supply pipe and thus must be correspondingly well insulated from the outside, the inner core pipe is only suitable for returning a relatively small part of the warm water directed to the hot water points to the hot water generator in order to to achieve a constant hot water cycle and thus to constantly provide hot water at the hot water points. It is particularly unsuitable as a double-pipe system for heating technology in which the water cooled in the heating elements can be traced.

The invention is therefore based on the object, a double pipe system o.g. To provide genre, with appropriate manufacturing processes and tools, through which manufacturing, assembly and storage are significantly simplified and costs are reduced.

This object is achieved by a double tube system with the features of claim 1. Advantageous embodiments are characterized in the subclaims 2 to 12.

The core tube, jacket tube and webs having double tubes and the matching double tube fittings are made, for example, from one piece from injection molded plastic. In this case, plug-in fittings are incorporated into the core and jacket tubes at the tube ends. Connection gradations are provided, which ensure smooth-walled transitions inside and outside when joining. The plug-in connection parts, which are preferably designed as corresponding connecting sleeves and connecting pins, can be joined together with a suitable adhesive to form a permanent, leak-tight unit.

The advantages associated with the invention are, in particular, the considerable simplification of assembly, since the individual parts of the double pipe systems, such as one-piece double pipes, connecting pieces and fittings, can each be plugged and glued together such that the core and casing pipes fit tightly into one another and that smooth-walled transitions without Projections or changes in diameter occur at the joints.

Furthermore, in a manner known per se, the inside of the pipes results in a significantly lower heat radiation of the transported liquid to the outside. In heating systems in particular, it is advantageous if the supply line to the radiators represents the inner core tube and the return line takes place in the outer jacket tube. In this way, an insulating effect for the hot liquid of the inner pipe is created by the somewhat colder liquid in the outer pipe, so that hardly any heat losses occur on the way to the radiators. In addition, the low heat exchange between supply and return prevents an undesirable temperature level and the resulting temperature shock in directly fired heat generators. The temperature adjustment devices otherwise required for this can be omitted. Unwanted circulation of the medium within a heat circuit during breaks in operation is prevented by the temperature compensation between the flow and return. This means that circulation blocks can be dispensed with. Another advantage is the significantly smaller space requirement of the double pipes in the installed state, since the outgoing and return lines do not have to be installed next to each other, but are designed one inside the other. In this way, hardly more space is required than for a single line with only one wall.

In addition, storage is simplified, since only piece-like double pipes and connecting pieces with an outer diameter are used that always fit together. Even with system sections of different lengths, separate cutting of inner and outer tubes is not necessary, since the double tubes always have core and jacket tube parts of the same length. As a result, only compact, easy-to-use system parts are required, and in a relatively small total number.

As already mentioned, it is advantageous that the one-piece double pipes have a step at their front ends both in the jacket pipe and in the core pipe, which correspond to the steps at the other end or with a further double pipe such that the double pipes are plugged together. and can be glued, there being smooth transitions on the inside and outside of the walls. These stages thus represent connecting sleeves with matching connecting pins, which enables a precise and seamless assembly of the individual parts without having to use any driving tool. The joining surfaces are designed to be so large that the plastic parts are firmly held together by gluing. The execution of the sleeves and spigots each on the same length on the core and jacket pipe ensures a high accuracy of fit of the pipes, without hidden gaps or joints in the core pipe are possible, which lead to leaks and passage of the transported medium could lead between the core and jacket tube.

Double tube angles can be achieved by parallel guidance of interconnected or one-piece core and jacket tubes in a tight bend. Of course, any combination and transition from a double pipe to two single pipes or single pipe branches from the core or jacket pipe are possible with the connection system. Such branches or distributors are possible by means of corresponding connecting pieces, which can also be designed at an angle. The pipe diameter can also vary, with the help of reducers that guide the core and jacket pipes evenly to smaller pipe diameters.

For example, a double pipe connector from a double pipe line can open into two single pipes, creating an angular branch from a double pipe to a core pipe and a casing pipe connection. Such a transition is e.g. necessary when connecting a radiator, since this does not normally have the hot water connection and the return line in the same place.

An advantageous embodiment is the optional attachment of internal and / or external threads on the one-pipe branches. This ensures that the double pipe connection system can be combined with other, conventionally screwed single pipe systems.

Branches of core or jacket pipe are also possible in that a double pipe has an angular branch to which a simple piece of pipe can be attached. The branch can either be led from the core tube through the jacket tube or - even more simply - start from the outer jacket tube. Of course, such an angular branch can also be designed such that the double pipe line branches into two further double pipe lines or that the double pipe line branches into two single pipe lines.

A double pipe reversing piece, which is necessary in a circulation line, is also advantageous. In this reversal piece, the casing tube is only open at one end, the other end is closed. The core tube ends openly in the jacket tube, so that a connection of the two lines is created, which enables a circulation flow from the core tube to the jacket tube or vice versa. For example, permanently hot water can be available at a tap by guiding the hot water in the core pipe to a branch pipe with a tap. If shortly after this branch the double pipe ends in a reversing section from which the hot water flows into the jacket pipe and is returned to the boiler, hot water is always immediately available at the point of use.

Of course, the double pipes can be made in different cross-sections, whereby connecting pieces and connecting pieces are also possible as reducers with a changing cross-section. Due to the different connection widths on both sides, any pipe cross-section can be combined.

The object is further achieved by a method for producing the system described above with the method steps according to claim 13.

Accordingly, one-piece plastic, with core, jacket and web parts made of plastic, for example, double pipes produced by extrusion are cut or cut to the desired length. Then the socket or spigot steps are milled into the jacket and core pipe at the same time on the double pipe ends for each end using a special tool. The corresponding socket and spigot surfaces are then coated with a suitable adhesive. Finally, these ends of two pipes to be joined are pushed together over their adhesive-coated sleeves and pegs until a mutual axial stop.

This makes it possible to cut the one-piece double pipe sections into any lengths and then to join them according to the principle of matching connecting sleeves and connecting pins. The one-piece brackets, connectors, reversing pieces, branches, reducers etc. also used in the system can already be equipped with suitable connecting sleeves and connecting pins. However, these connection points can only be introduced during assembly using the same tools as for the straight double pipe sections. It can be seen that this gives the relatively inexperienced handyman the opportunity to provide the double pipe system quickly and easily and in a very precise and well-sealing design.

Finally, the object is achieved by the tools for carrying out the above-described production method, with the characterizing features of claims 15 and 16, respectively.

Accordingly, a milling cutter is provided for insertion into the double pipe ends of the connecting pins, which has two machining zones arranged concentrically to one another, each consisting of a milling cutter for parallel external machining of the casing tube and the core tube, ie an exact milling to the dimension of the connecting journal, so that a suitable connecting sleeve can be connected to the machined end. Concentric to the machining zones, a guide pin concentric to the machining zones for centering the milling cutter in the core tube is provided in the forward axial direction, while projecting in the opposite, axial direction, also centrally and simultaneously concentrically to the machining zones, a drill holder for clamping the milling cutter, e.g. in a known chuck of a hand drill is provided.

The milling tool is designed in a similar way for insertion into the double pipe ends of the connecting sleeves, namely with an axially protruding guide pin for centering the milling cutter in the core tube and a central, axially protruding rearward drilling machine holder for clamping the milling cutter in a hand drill, but here the two machining zones, which are arranged concentrically to one another and to the guide bolt and the drill holder, are for parallel internal machining of the casing tube and the core tube, ie for precise milling to the size of the connecting sleeves.

It can be seen that the respective end-side connecting stages, ie connecting sleeves or connecting pins, can be introduced quickly, easily, securely and very precisely with the two tools according to the invention. The user only has to clamp the respective tool in his hand drill, axially insert the relatively long guide pin into the core tube of the correspondingly cut double tube, until the end face of the milling cutter teeth is brought close to the end face of the double tube. Then the hand drill is activated and the milling cutter continues on or into the double pelrohr inserted, up to the axial stop between the pipe end and the depth stop of the tool between the two concentric toothings, whereby the corresponding steps are incorporated precisely in diameter and length. Then the tool must be removed from the double pipe and replaced with the next tool in order to insert the appropriate steps in the corresponding next double pipe end.

The invention is explained in more detail below on the basis of exemplary embodiments with reference to the drawings. Show it:

1: a schematic representation of a double pipe installation of a closed heating water circuit with two different radiator connections,

2: a schematic representation of a double pipe installation of a closed hot water circuit and a single pipe process water connection,

3: a part of a one-pipe system, in a longitudinally sectioned exploded view,

4 shows a double tube angle, in longitudinal section,

5 is a double pipe connector, in longitudinal section,

6 is a double tube, in cross and longitudinal section,

Fig. 7 is a double tube reversal piece _. in longitudinal section,

8 shows a longitudinally cut double pipe flow T-piece with a core pipe single pipe branch,

9 shows a longitudinally cut double pipe feed tee with a jacket pipe single pipe branch, FIG. 10: a longitudinally cut double pipe tee and a corresponding double pipe reducer, FIG. 11: a longitudinally cut double pipe distributor with a single pipe -Core pipe connection and a single pipe jacket pipe connection as well as a corresponding threaded connection nipple, 12: an axial section through a milling tool for introducing connecting sleeves into a double pipe, and

13: an axial section through a milling tool for inserting connecting pins into a double pipe.

In Fig. 1, a double pipe installation for a closed heating water circuit with two different radiator connections is shown. From a boiler 21, two single-pipe lines lead to a double-pipe connection piece 10. The line for hot water opens into the core pipe connection 31, while the return line for the cooled water at the casing pipe connection 32 of the double-pipe connection piece 10 (see FIG. 5 ) connected. On the double pipe connector 10, a double pipe of the required length, consisting of several double pipe sections 11 which are plugged together and glued together, is connected. For the correct laying of the pipeline from the location of the boiler 21 to the radiators 19, the double pipe sections 11 can optionally be connected by double tube angles 9. A double pipe flow T-piece 13 with a core pipe branch allows the supply to the radiator 19 via a single hot water pipe, consisting of simple pipe sections 7, a single pipe angle 4 and a connecting nipple 18. At a location with, for example, two radiators 19 after the return of the colder water by means of a double pipe flow T-piece 14 with a branch pipe branch, a double pipe reducer 16 should expediently be provided, since only half the total amount of water is passed through the line leading to the second radiator 19. The branching of hot water and recirculated water takes place here through a double pipe distributor 17, which branches off the core pipe at a 90 ° angle and continues the jacket pipe into a simple pipe section 7. Further necessary fittings are not shown in FIG. and devices such as pumps, valves, etc.).

2 shows a double pipe installation for a closed hot water circuit with single pipe process water connections. A hot water and a return line lead from a hot water boiler 22 and open into a double pipe connection piece 10. From this, a double pipe, consisting of several double pipe sections 11 and possibly connected with double pipe angles 9 for 90 "bypass, leads to a double pipe T-piece 15, from which two double pipe reducers 16 branch off. The pipe cross sections of the branched double pipes , again consisting of several double pipe sections 11 and possibly connected with double pipe angles 9, can be smaller since they each only carry half of the total amount of water. In the immediate vicinity of the wash basin 20, the double pipe sections 11 open into a double pipe flow -T piece 13, in which a branch of the core pipe leads to the hot water connection of the wash basin 20. In order to always be able to immediately provide hot water to the wash basin 20 without delay, there is a double pipe feed T piece behind the branch 13 double tube reversing pieces 12 are provided in each case (see also FIG. 7), in which the core tube to the jacket r open to the ear and the jacket tube is closed to the outside. As a result, the hot water can run from the core pipe into the casing pipe and be returned to the hot water boiler 22 via the casing pipes. In Fig. 2, an additional one-pipe cold water line 2 is also drawn, the one-pipe connection angle 8, simple Rohrstüσke 7 with possibly interposed one-pipe angles 4, a branch on a one-pipe T-6 via simple pipe sections 7 and Single tube angle 4 leads to the single tube connection angles 3 on the wash basin 20. 3 shows a single-pipe line, similar to the cold water line 2 shown in FIG. 2, the elements of which are joined together in essentially the same way as those of the double pipe described above. The line consists of a single-pipe connection bracket 8, which has an external thread 27 at one end and a connection pin 24 at the other end. Then one behind the other are a simple pipe section 7, which can either be very long or can be assembled from several shorter sections, a monotube T-piece 6, a monotube reducer 5 which tapers towards the further end, a monotube angle 4 and finally a one-pipe connection bracket 3, which has an internal thread 28 at the outer end, is arranged. All of these elements each have a connecting sleeve 23 at one end and a matching connecting pin 24 at the other end, so that after the joining, the outer and inner walls have a smooth transition without steps or steps. The front steps, or the connecting sleeves 23 and connecting pins 24, can be introduced from the beginning, ie during extrusion, or subsequently during installation, by means of special milling tools, similar to those for the double tube steps.

Fig. 4 shows a double tube angle 9, consisting of a core tube 29 which is connected to a jacket tube 30 via centering webs 25. The double pipe angle 9 kinks the line by 90 ° and has at one end, in each case on the core pipe and on the jacket pipe incorporated connecting sleeves 23, while at the other connecting end connecting pins 24 are incorporated.

Fig. 5 shows a double tube connector 10, consisting of a core tube 29 and a jacket tube 30, which has connecting sleeves 23 at the double tube end. The casing tube 30 opens straight or axially into a jacket tube connection 32 with an external thread 27. The core tube 29 is angled by 90 ° and opens into a core tube connection 31 with an external thread 27.

6 shows a double tube section 11, consisting of a core tube 29, a jacket tube 30 and centering webs 25. Connection sleeves 23 are incorporated at one end, connection pins 24 at the other end, each on the corresponding core tube 29 and jacket tube 30.

The double-tube reversing piece 12 shown in FIG. 7 consists of a core tube 29 set off in the jacket tube 30, with a connecting pin 24. The core tube 29 ends openly, axially spaced, in the jacket tube 30 which is closed at the top, as a result of which the two lines are connected.

In Fig. 8, a double pipe flow T-piece 13 is shown, which has a 90 ° branch 33 in the core tube, which is passed through the jacket tube 30 to the outside and has a connecting sleeve 23 at the end. The double pipe flow T-piece 13 also has connecting sleeves 23 or connecting pins 24 at its ends.

FIG. 9 shows a double pipe flow T-piece 14 with a 90 ° branch 34 in the jacket pipe 30. The core pipe 29 is continuous, only the jacket pipe 30 has a jacket pipe branch 34 with an integrated connecting sleeve 23. The double pipe inlet T piece 14 has connecting sleeves 23 and connecting pins 2.

10 illustrates a double pipe T-piece 15 and a double pipe reducing piece 16. The double pipe T-piece 15 has a common 90 ° branch for the core pipe 29 and the casing pipe 30 on. The branch has a connecting sleeve 23, while connecting sleeves 23 and connecting pins 24 are provided at the other two connection ends. The double pipe reducer 16 can be connected to the branch, which tapers in cross section and has connecting sleeves 23 and connecting pins 24. The core tube 29 and the jacket tube 30 are firmly connected by a plurality of centering webs 25 arranged in the circumferential and longitudinal directions.

Fig. 11 shows a double pipe distributor 17 and a connecting nipple 18. In the double pipe distributor 17, the core tube is just continued and ends in a core tube connection 35 with a connecting sleeve 23, while the jacket pipe branches off at a 90 ° angle and in a jacket pipe -Connection 36 with connecting sleeve 23 ends. A connecting nipple 18 can be connected to the tubular casing connection 36, which has a connecting pin 24 at the end corresponding to the tubular casing connection 36 and has an external thread 27 at the other end. A wrench receptacle 26 is incorporated in the center of the outer jacket of this connecting nipple 18.

Fig. 12 in turn shows a double pipe section 11 after being cut to a certain size and a milling tool 41 for simultaneous milling of a step in the core pipe 29 and casing pipe 30, i.e. for inserting the connecting pin 24. It has a central, pin-shaped drill holder 43, a likewise central guide pin 44 and two coaxial cutter teeth 45 and 46 for the casing tube 30 and the core tube 29, respectively. This cut-to-length piece 11 can be joined together with the suitable connecting sleeves 23 of further individual parts of the double-pipe connecting system.

13 finally shows the longitudinal section of a double Pipe section 11 after cutting to a certain size and a milling tool 42 for simultaneous milling of a step in the core tube 29 and jacket tube 30, ie for introducing the connecting sleeves 23. It also has a drill holder 43, a guide pin 44 and two cutter teeth 47 or 48 for the casing tube 30 or the core tube 29. So this cut piece can be assembled with the matching connecting pin 24 further individual parts of the double pipe connection system.

B e z u g s z e i c h e n l i s t e

1. 29 core tube

2. Cold water line 30

3. Single pipe connection bracket 31. Core pipe connection

4. One-pipe angle (external thread)

5. Single pipe reducer 32. Jacketed pipe connection

6. One-pipe T-piece (external thread)

7. Simple pipe section 33. Core pipe branch

8. Single pipe connection bracket 34. Branch pipe branch

9. Double tube angle 35. Core tube connection

10. Double pipe connection piece 36. Jacket pipe connection

11, double tube section 37.

Double pipe reversing piece 38.

13, double pipe flow tee 39.

(Core pipe branch) 40.

14, double pipe advance T-piece 41. milling tool (for (casing pipe branch)) (external machining)

15. Double tube T-piece 42. Milling tool (for

16. Double pipe reducer (internal machining)

17. Double pipe distributor 43, drill holder

18. Connection nipple 44. Guide pin

19. Radiator 45

20.Washbasin (casing pipe)

21. Boiler 46, cutter teeth

22, hot water boiler (core tube)

23. Connection sleeve 47, cutter teeth

24, connecting pin (casing tube)

25, centering webs 48, cutter teeth

26 Fork key holder (core tube)

27, external thread 49

28 internal thread 50

Claims

PATENT CLAIMS

1. Double pipe system, in particular for heating, plumbing, refrigeration and process engineering with double pipes, each composed of a jacket pipe, which are spaced coaxially apart via radial webs, characterized in that the double pipes (11) of the system are each made in one piece from plastic are manufactured and have corresponding plug-in connection gradations (23, 24) on their end faces, both in the casing tube and in the core tube part, for assembling and gluing together the system parts, each with smooth wall transitions inside and outside.

2. Double pipe system according to claim 1, characterized in that on the one hand connecting sleeves (23) and on the other hand with these corresponding connecting pins (24), are provided as opposed connector gradations on the double pipes by opposite diameter steps of the same length.

3. Double pipe system according to claim 1, characterized in that single pipe and double pipe lines can be combined in the system by corresponding connecting pieces and branches.

4. Double pipe system according to claim 3, characterized in that a double pipe connector (10) is provided with a double pipe part, consisting of core tube (29) and jacket tube (30), which opens into two individual tubes at an angle to one another, so that there is a branch from a double pipe to a core pipe connection (31) and to a casing pipe connection (32).

5. Double pipe system according to claim 4, characterized in that the double pipe connection piece (10) at its single pipe branches, that is, at the core pipe connection (31) and at the casing pipe connection (32) each have an external thread (27) or an internal thread ( 28).

6. Double pipe system according to claim 3, characterized in that a double pipe angle (9) is provided in which the core pipe (29) and casing pipe (30) are guided parallel to each other in a tight bend.

7. Double pipe system according to claim 3, characterized in that a double pipe lead T-piece (13) has a core pipe branch (33) by a double pipe consisting of core pipe (29) and jacket pipe (30) an angled branch of Has core tube (29), to which a simple piece of pipe (7) can be attached.

8. Double pipe system according to claim 3, characterized in that a double pipe flow T-piece (14) has a casing pipe branch (34) by a double pipe consisting of core pipe (29) and casing pipe (30) an angled branch of Has core tube (30), to which a simple piece of pipe (7) can be attached.

9. Double pipe system according to claim 3, characterized in that a double pipe T-piece (15) has a common angular branch of the core pipe (29) and jacket pipe (30), so that a double pipe can be branched into two double pipes.

10th Double pipe system according to claim 3, characterized in that a double pipe distributor (17) is formed by separating the core pipe (29) and the casing pipe (30) into two separate connections which are at an angle to one another, whereby a double pipe in two single pipes connected to a core pipe -Connection (35) and to a casing pipe connection (36), opens.

11. Double pipe system according to claim 3, characterized in that a double-tube reversing piece (12) is formed by forming a core tube (29) which is offset in the closed tubular tube (30) and ends openly in the tubular tube (30), a connection of the two Lines are formed.

12. Double pipe system according to claim 3, characterized in that a double pipe reducer (16) with different connection widths on both sides and a parallel cross-sectional constriction of the core pipe (29) and casing pipe (30) is provided.

13. A method for producing the system according to claims 1 to 12, comprising the following steps: a) double tubes, made of plastic in one piece. B. produced by extrusion, with core, jacket and web part or parts, are cut or cut to the desired length, forming double tube sections (11), b) at the double tube ends are then in one operation for each end , each with a special tool, simultaneously milled the socket or spigot steps on the casing and core tube, c) the corresponding socket and spigot surfaces are then coated with a suitable adhesive, d) and finally the ends of two pipes to be joined are pushed together over their adhesive-coated sleeves and pegs until a mutual axial stop.

14. The method according to claim 13, characterized in that the further elements of the double tube system, such as double tube angle (9), connecting piece (10), reversing pieces (12), flow T-pieces (13, 14), -Reducing pieces (17) and -distribution piece (17) are made in one piece from plastic and have connecting sleeves (23) or connecting pins (24) at their connecting ends.

15. Tool for carrying out the method steps of the introduction into the double tube ends of the connecting pins, gladly claim 13, characterized in that it is designed as a milling cutter (41) which a) has two processing zones arranged concentrically to one another (45, 46), b) one the machining zones (45, 46) concentric guide bolts (44) for centering the milling cutter (41) in the core tube (29), and c) a drilling machine holder (43) concentric with the machining zones (45, 46) for clamping the milling cutter (41), for example in a drill chuck of a hand drill known per se, the processing zones each consisting of a milling cutter (45, 46) for parallel external machining of the casing tube (30) and the core tube (29), ie an exact milling to the dimension of the connecting pins (24) , consists.

16. Tool for carrying out the method step of introduction into the double tube ends of the connecting sleeves gladly claim 13, characterized in that it is designed as a milling cutter (42), the a) two concentrically arranged machining zones (47, 48), b) one of the Machining zones (47, 48) concentric guide bolts (44) for centering the milling cutter (41) in the core tube

(29), and c) a to the machining zones (47, 48) concentric drill holder (43) for clamping the cutter (41) z .B. in a known drill chuck of a hand drill, the machining zones from a milling cutter (47, 48) for parallel internal machining of the casing tube (30) and the core tube (29), i.e. a precise chamfer on the dimension of the connecting sleeves (23).