DE3018781A1 - Pipe with thermal insulation - has woven fibre coating, surrounding hollow ring chamber, and outer metal protective jacket - Google Patents

Abstract

The pipe has heat insulation and a protective jacket, and is for warmed or cooled media, e.g. fluids, steam, or gas. The pipe (1) consists of a non-rust metal of high rigidity, and a coating (2) of woven fibres engages on the pipe exterior. The coating consists of a woven band (10) of glass- or asbestos fibres, wound straight or helically around the pipe. A hollow ring chamber (3), extending over the whole length of the pipe, is formed between or around the fibre coating. The chamber is evacuated, or filled with a neutral gas, and it is surrounded gas- and humidity proof by a metal protective jacket (4). A leakage monitor wire (19) and/or a measuring- resp. control signal transmission wire (18) is located in the jacket. An anti-corrosion jacket (8,9) surrounds the metal jacket.

Description

Thermally insulated conduit

The invention relates to a thermally insulated, with thermal insulation and protective sheath prefabricated conduit pipe in reelable lengths, according to the generic term of claim 1.

It finds universal application for the transport of heated or of cooled media such as liquids, vapors or gases over long distances.

Typically, such pipelines are predetermined Routing made of individual pipes that can be transported in the stretched state accordingly Length assembled and subsequently by hand with heat-insulating mats or with loose glass or

Rock wool insulated, as well as with a protective coat made of it surrounded by thin sheet metal, which in turn is galvanized or painted Corrosion must be protected. Apart from this cumbersome and therefore costly Mounting and thermal insulation of this may not be as effective as it is desirable would be, because the pipes insulated in this way with their fastening elements, e.g. clamps or welded-on double T-beams on plain bearings predominantly made of metal are attached, the good heat conductive contacts with the often also heat conductive Supporting structure and so have a considerable share of the heat of the transported Release medium to the environment.

It is already from CH-PS 459 584 a low-temperature cable for energy transmission known, the head of which is enclosed by thermal insulation, consisting from evacuated cavities delimited by concentric corrugated pipes.

This is a prefabricated one in reelable lengths Thermal insulation, however, this very special purpose of cooling the cryogenic conductor except for a few degrees K. For a universally applicable and lightweight Mountable pipeline such as district heating pipeline or the like is such an insulation structure not justifiable for economic reasons. Added to this is another essential one Disadvantage of every corrugated pipe that is in the medium to be transported Turbulence is caused, and the more so, the higher the flow velocity of the medium to be transported, which leads to a significant reduction in the Transport performance of such a pipeline leads.

However, one known from DE-OS 16 50 060 also has the same disadvantage flexible conduit made of concentric metal tubes with a helical or bellows-shaped Corrugation, of which at least two are used to convey the medium, the Gaps between the walls of these pipes with a thermally insulating Layer of foam are filled. A significant disadvantage of this in reelable Lengths of prefabricated conduit, however, also consists in the fact that it is not universal can be used, for example, when transporting media with extremely high or low temperatures the thermoplastic thermal insulation between the pipes suffer damage, in particular would soften or become brittle.

The same disadvantage also has a known from DT-OS 22 00 606, Plastic-coated, corrosion-proof, heat and sound insulated Metal tube for increased external pressure, which is designed as a smooth tube is. This has a plastic jacket in which longitudinal cavities with are designed towards the inside tapering partition walls. Hence there is a risk a softening and deformation of these partitions when transporting highly heated media. At low temperatures, the resulting brittleness of the plastic insulating material lead to breaks, especially in the area of these partitions. To this comes another Disadvantage that with the increasing shortage of petroleum products, including plastics, the production of such plastic insulation is becoming more and more complex, which results the need arises from this by others in terms of their low thermal To replace conductivity at least equivalent substances.

With the known thermally insulated pipelines, there is no possibility of Damage to existing moisture barriers, such as an outer protective cover to be able to locate and repair, to maintain the good efficiency of the thermal insulation. Likewise, there are no facilities for the signal transmission of measuring or control pulses, However, these are necessary as the cable length increases, be it for remote control of switching elements such as flow regulators, shut-off devices or the like, but also to control or control the temperature of the pipe or the transported Medium.

The invention is based on the object of providing a universally applicable, to create thermally insulated conduit pipes prefabricated in reelable lengths, using mineral insulating materials in a simple manner in great lengths can be manufactured, transported and laid and furthermore for signal transmission and is set up for easy fault location. This task is carried out by the invention characterized in claim 1 solved.

Advantageous refinements and developments of the invention are with the subclaims 2 to 10 indicated, of which claim 2 is based on the selection of the line pipe material relates and claims 3 to 5 different Refinements of the annular cavity relate to which at the same time the thermal insulation as well as the passage of a tracer gas for fault location. The requirements 6 to 8 relate to the facilities of the conduit for its heating respectively.

Signal transmission, while claims 9 and 10 the formation of the Protective jacket, including its corrosion protection, concern.

The advantages of the invention are mainly that from these Line pipes composed lines for a flow vortex-free transport any media with the greatest possible flow velocity are well suited, according to their smooth inner pipe wall, which is also preferably connected to the protective gas Butt welded pipe connections between delivery lengths no diameter narrowing having. Because of the special properties of the pipe material used for this purpose, In particular, a special stainless steel, the pipeline can also be used for transport aggressive media are used. In addition, because the thermal insulation is made of mineral Consists of basic materials, this thermally insulated pipe is for extremely high or low operating temperatures can be used if, for example, coolant are to be transported. With such a line, heat losses are over any Fastening devices excluded, as these are always on the outer jacket over the attack thermal insulation.

The pipeline is also suitable for this purpose - in addition to being transported at a temperature Media - also transmit high-frequency control impulses that may be necessary for a installed pressure monitoring of the system itself are required, or for the Transmission of measured values or other signals. This makes the parallel one unnecessary Laying a control cable, especially between a metal jacket and the outer protective sheath can also be arranged control and / or signal lines. The at the same time between the metal jacket and the outer protective cover on the circumference Distributed leak monitoring wires loosen if the outer ones are damaged Protective cover emits a signal. But it can also be in the area of the pipe or the protective sheath measuring wires are arranged, the change in resistance for the total measurement the pipe temperature can be used.

Apart from the corrosion protection, the pipe consists only of petroleum product-free Materials, and its manufacture can be carried out without difficulty on conventional manufacturing facilities about a cable manufacturer. Furthermore, the invention enables cost-saving Way the production of this conduit in great lengths, which is easy to lay can be, with the ends of two such conduits only at large intervals by means of special welding without narrowing the passage cross-section get connected. This requires the transport of tempered media with high flow velocities, whereby heat losses are very low.

Assembled from the reelable production lengths of this conduit pipe Thermally insulated pipelines can be used without reducing their efficiency also in areas with extreme outside temperatures both in the air and directly in Earth can be laid without tension at the welded joints occur, with complex underground structures such as district heating ducts or such a thing is superfluous.

This is also the case with this conduit, if dimensioned accordingly its thermal insulation also enables it to cross bodies of water without significant heat loss possible. However, the pipe can be bent at appropriate points or if necessary Loops are laid to compensate for different linear thermal expansions.

Essential for the high thermal resistance of these Insulation is the absolute tightness of the protective jacket against moisture, so that the good efficiency of the thermal insulation is maintained. To this function to guarantee the protective jacket as a moisture barrier under all circumstances, on the one hand, the annular cavity is provided, which for easy location of any Leaks with a tracer gas, e.g. a mixture of nitrogen and helium, can be filled. For this purpose, there is also at least one leak detection wire in the area of the jacket arranged, the corresponding circuits with a leak alarm device is connected. Corrosion protection by means of a gut is also important here adhesive, moisture-repellent corrosion protection layer underneath a chemical and electrical environmental influences resistant outer shell. Essential but is also the establishment of this conduit for the transmission of high frequencies Measured value or control pulses, which via appropriate coupling devices directly over the pipe or the protective jacket or via the one in the area of the protective jacket arranged measuring and / or control signal transmission cores or a multi-core line can be done.

For many purposes, the establishment of the pipe is for its Heating is very beneficial, e.g. for the transport of highly viscous liquids. For this can use the tube itself for the flow of a heating current of low voltage and Large amperage can be set up by placing at one end of the several manufacturing lengths composite pipeline the pipe and the metallic protective jacket on several Set their scope for the connection of one pole or phase of a power source, e.g.

Transformer, are set up, being at the removed therefrom Pipe end electrically conductive the insulated pipe in a star-shaped arrangement is connected to its protective sheath. If this is a low frequency Heating current can - if necessary - at the same time also the high-frequency Control pulse transmission take place via with appropriate Filter equipped and between a pulse generator or receiver and the pipe or its jacket intermediate coupling devices. However, the pipe can also with an electrical one that immediately surrounds it within the thermal insulation Heating wire coil be equipped, which in sections with an electrical Power source is connectable. This allows the heating of the pipe to be better controlled, e.g. if only part of the pipeline or at regular intervals recurring Sections of the same need to be heated.

The invention is illustrated below with reference to in the drawing Embodiments explained in more detail.

The drawing shows: FIG. 1 in view with partially removed Protective jacket an embodiment of the thermally insulated conduit pipe, Fig. 2 shows a cross section through this conduit, FIG. 3 in a view with a partially removed Protective jacket, another embodiment of this thermally insulated conduit pipe and FIG. 4 shows a cross section through the conduit pipe according to FIG. 3.

The embodiment shown in Fig. 1 and 2 can be with little Produce effort, while the embodiment shown in Figures 3 and 4 able to meet the highest requirements.

In all drawing figures, the line pipe is denoted by 1, which as a smooth tube made of a metal selected according to the application is trained. In addition to copper, a stainless steel is used for this purpose the group of chromium and nickel as well as possibly titanium, niobium molybdenum and the like additives under alloyed stainless steels with a carbon content 12 ffi preferred. Clear width and wall thickness of the Rohres 1 are coordinated in such a way that it is sufficient, including its thermal insulation is flexible, so that it can easily be applied to a drum in long production lengths for transport to the installation site.

In each embodiment, the tube 1 is with at least one of these Surface immediately adjacent layer 2 of a fiber fabric enclosed, the made of a lengthwise or helical around the tube 1 around the fiberglass or asbestos fiber fabric tape 10. So this is a mineral one Material of extremely low thermal conductivity, which is in this form, namely, as a fabric tape, very easily applied by machine to the pipe to be insulated leaves.

Between or around the fiber fabric layers 2 is an evacuated or formed with a tracer gas filled annular cavity 3, which extends over the entire Pipe length extends. The annular cavity 3 surrounding the fiber fabric layers 2 is in one embodiment by a plurality of these fiber fabric layers 2 formed in an open spiral nubbed tape 6, which is a metallic jacket 4 is applied immediately. The one created under the metallic protective jacket 4 Annular cavity 3 can include all spaces between the layers and fibers the multilayered thermal insulation formed from the fabric tape 10, which no Contains intermediate layers to be evacuated to increase the thermal resistance. However, it can also be used continuously or occasionally with a neutral that is under excess pressure Gas, e.g. a mixture of nitrogen and helium, to check for leaks of the protective jacket 4 and for leak location. The knobbed tape 6 can be made of any consist of easily permanently plastically deformable material, e.g. a press film Cellulose fiber or mineral fiber base. However, it is preferably made of a bare one Metal foil formed, which by its reflective property the effectiveness of the Ability to increase isolation. At the same time, it creates that to a sufficient extent previously described annular cavity 3, with - there only punctiform - minimal contact with the metallic protective jacket 4, e.g. made of aluminum.

Instead, the annular cavity 3 is the one shown in FIGS. 3 and 4 shown embodiment of this conduit between each a number of inner and outer fiber fabric layers 2 arranged from the fabric tape 10, which respectively forming an inner and an outer cushion layer 11 and 12 respectively, the annular cavity 3 within the outer cushion layer 12 with a bare metal foil 5 directly is enclosed. This is the circumferential surface of a number concentrically around the inner cushion layer 11 arranged annular spacer 13 on, like this can best be seen in Fig. 3. In this way, a low-contact becomes larger evacuable annular cavity 3 correspondingly greater thermal insulation capacity than formed in the previously described embodiment of this conduit pipe.

For a simple process of manufacturing this conduit embodiment the spacers 13 consist of at least two complementary to each other to the ring shape and parts 16, 17 formed with passages 15 made of a mechanically strong material with low thermal conductivity, e.g. a ceramic material, which are held together by means of a looped spring ring 14 or the like. For an exact centering of the tube 1 within the refluxing envelope bare metal foil 5 with the outer padding 12 and metallic Protective jacket 4 or 7 and for precise mutual adaptation, the parts 16, 17 of the spacers 13 on their mutually facing surfaces with a form-fitting Means such as tongue and groove or the like can be formed.

Depending on the dimensions of the clear width and the thermal insulation of the pipe 1 can have its metallic protective jacket either as a smooth pipe or - as shown in FIGS. 3 and 4 - designed as a corrugated jacket 7 be. In any case, between the metal jacket 4 or 7 and a surrounding one of these Protective cover 9 one at the corrugated jacket 7 of which Filling valleys Corrosion protection layer 8 from a plastic or rubber regenerate or from a Mass arranged on betumen base or a mixture of these substances. The anti-corrosive layer 8 is from the shell 9 extruded over it made of an environmentally resistant material, e.g. plastic or rubber, enclosed.

Monitoring wires8 are inside or outside the protective jacket 4 or 7 and / or signal transmission or control cores 19 arranged circumferentially distributed, preferably roped onto the metal jacket 4 or 7 and from the outer protective sheath 9 enclosed, wherein they are at least partially embedded in the corrosion protection layer 8 are. This brings advantages in terms of manufacturing technology. It is essential here but that the leak indicator is already damaged when the outer Protective cover 9 or the anti-corrosion layer 8 responds.

This will - what with such long-term in the ground and possibly The most to be feared of pipes laid in water is corrosion of the Moisture-proof protective jacket 4 and 7 excluded, since any such damaged area is displayed immediately so that it can be located and repaired in good time, before corrosion-related damage to the moisture-proof protective jacket 4 or 7 or even leaks arise.

In addition, in the event of mechanical damage to the protective jacket 4 and 7 also within the same, for example in the space between its inner surface and the outer cushion layer 12, also leak monitoring wires 19 or others Transmission or control cores 18 may be arranged.

All embodiments of this conduit show excellent thermal insulation ability as a result of the sensible combination of their layered Fiberglass fabric tape insulation with an evacuated or filled with neutral gas cavity on. A pipeline made from it is therefore for the transport of a wide variety of media, including those with extremely high or low levels Temperatures and under various environmental conditions are extremely well suited.

Claims (1)

Claims: 5., Thermally insulated, with thermal insulation and protective jacket Line pipe prefabricated in reel lengths for heated or cooled media such as liquids, vapors or gases, which is designed as a smooth tube made of a metal is a combination of the following features: a) the tube (1) is made of a high-strength stainless metal, b) the Tube (i) has at least one layer directly adjacent to its surface (2) Enclosed a fiber fabric, consisting of a longitudinal or helical Glass or asbestos fiber fabric tape (10) placed around the pipe, c) between or around the fiber fabric layers (2) is an evacuated or with a neutral Gas-filled annular cavity (3) is formed, which extends over the entire length of the pipe extends, d) the annular cavity (3) is covered by a metallic protective jacket (4, 7) Enclosed gas- and moisture-tight, e) in the area of the metal jacket (4, 7) is at least one leak monitoring wire (19) and / or a measuring or Control signal transmission wire (18) or multi-wire line arranged, f) a corrosion protection outer shell (8, 9) is arranged over the metal jacket (7). 2. Line pipe according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that the pipe material is made to match the intended use the group of stainless steels, namely with chromium, nickel and possibly titanium, Niobium and / or molybdenum alloy steels, is selected. 5. Line pipe according to claim 1 or 2, d a d u r c h g e -k e n n it is noted that the annular cavity (3) is surrounded by a plurality of the fiber fabric layers (2) nub tape (6) wrapped around in an open helix is formed, to which the metallic Sheath (4) rests directly 4. conduit pipe according to claim 1 or 2, d a d u r c h g e -k e n n n z e i c h n e t that the annular cavity ()) between cushion layers (11, 12) arranged from the fiber fabric tape (10), and inside the outer cushioning layer (12) is directly enclosed by a bare metal foil (5), which is the peripheral surface a number of annular ones arranged concentrically around the inner cushioning layer (11) Spacer (13) is applied. 5. Line pipe according to claim 4, d a d u r c h g e -k e n n z e i c h n e t that the spacer (1)) consists of at least two each other to form a ring shape supplementary and with passages (15) formed parts (16, 17) from a mechanical solid material with low thermal conductivity, e.g. a ceramic Material, exist, which by means of a spring ring (14) or the like wrapped around. held together are. 6. Line pipe according to one of claims 1 to 5, d a -d u r c h g e k e n n n z e t c h n e t that it is set up for the flow of a heating current or within the fiber fabric layers (2) by an electrical heating wire coil is surrounded. 7. Line pipe according to one of claims 1 to 5, d a -d u r c h it is not indicated that the pipe (1) and / or the metallic jacket (4, 7) is set up for high-frequency measurement or control signal transmission. 8. Line pipe according to one of claims 1 to 7, d a -d u r c h g It is not indicated that the monitoring wires (18) and / or signal transmission or control cores (19) circumferentially distributed around the metal jacket (4, 7), preferably on this, and are enclosed by the outer layer (9). 9. Line pipe according to one of claims 1 to 8, d a -d u r c h it does not indicate that the metal jacket is a seamless corrugated jacket (7) formed, with a die between this and the outer protective sheath (9) Corrosion protection layer (8) made of a plastic material or filling wave troughs Reclaimed rubber or a compound based on betumen or a mixture of these substances is arranged. 10. Line pipe according to one of claims 1 to 8, d a -d u r c h It is not noted that the metal jacket is over the fiber fabric layers (2) seamlessly applied smooth tube (4) and formed by one over the anti-corrosion layer (8) extruded sheath (9) is enclosed.