DE3232211A1 - Medium transportation line - Google Patents

Abstract

In a medium transportation line having an inner pipe which is used for transportation and at least one sensor, which is arranged outside the inner pipe and is provided with a covering layer which is used for protection and insulation, said covering layer consists of a material which absorbs water at specific temperatures, while changing its electrical properties, especially the resistive and capacitive impedance. As a result of this temperature dependency, it is possible to determine whether, for example, hot water is escaping from a remote-heating line or cold water has penetrated into the line from the exterior.

Description

Medium transport line

The invention relates to a medium transport line, in particular District heating pipe, with an inner pipe serving for transport with at least one arranged outside the inner tube, which is used for monitoring and fault location Sensor provided with a protective and insulating cover layer is.

With the help of such known medium transport lines one can with the help of the sensor determine the location of the occurring water and thus also the presence of a possible leak in the transport line. However, there is the disadvantage that it cannot be determined whether the occurrence of water has actually occurred originates from pure leakage of the transport line or whether it is not water from the outside has penetrated the medium transport line.

In addition, the previous sensors in the transport line have a possible damage to the sensor occurred more frequently, which affects the display or failed at all by the perforation through which the water was used for the measurement must occur, offered special points of attack for mechanical damage.

The invention is therefore based on the object of a medium transport line to make available with a sensor, the determination with an increased operational safety enables whether a medium is leaking or water has entered the line from outside is.

This object on which the invention is based is achieved by that in the case of a bfediuTatransportleitung the aforementioned.; \ rt the cover layer of the sensor is made of a material that i4 # sst at certain temperatures:; r while changing its elextriscltell properties th, in particular of the ohmic and / or capacitive resistance. In an advantageous Embodiment of the invention provides that the cover layer in the sensor is applied to sensors of any spatial shape, which are spaced along the medium transport line for pulse reflection measurement are connected by an insulated conductor.

Another embodiment is characterized in that the sensor consists of at least one reporting wire which is surrounded by the cover layer.

It can be provided in an advantageous manner that the message headers has a cover layer which penetrates the water only when the water is warm enables. In such a case, the cover layer is expediently made of polyurethane, preferably polyurethane foam.

It can also advantageously be provided that the message head has a cover layer which only allows the water to penetrate when the water is cold. Appropriate such a cover layer consists of polyamide.

According to a development of the invention, two message wires are included different temperature characteristics provided. The two message wires with different temperature characteristics separated outside the inner tube be arranged, or the two message wires of different Teinperaturcharakteristik are combined to form a signal cable. In this case there is an appropriate one Embodiment is that the one message head with a cover layer of a first Material is provided and with the other reporting line from a common cover layer is enclosed from a second material.

The sensor is expediently at the lowest point of the long-distance line or in a concrete channel with a sloping bottom at its deepest Place arranged.

In the following, the invention is intended to be based on exemplary embodiments with reference to the bCj ~ S: ei'ugt Drawings explained in more detail will. In the drawings: FIG. 1 shows the cross section through a medium transport line with feeler; 2 shows the cross section through a signaling cable consisting of two signaling wires; 3 shows the cross section through a medium transport line comprising a concrete channel; 4 shows the cross section through another embodiment of a medium transport line and FIG. 5 shows a graph of the dependence of the resistance on the Temperature for material 4 en of the cover layer of the sensor.

A medium transport line 1 is shown in FIG. It includes an inner tube 2 made of steel, which is used to transport liquids: or Gases is used. A preferred form of application is the transport of heat in district heating lines. The inner tube 2, which normally has a wall thickness of 3 mm, is of a Surrounding insulating layer 3 for thermal insulation. This insulating layer 3 is preferably made made of a rigid plastic foam such as polyurethane. The insulating layer 3 is after closed on the outside by a sheath 4, which consist of a hard polyethylene can. While the insulating layer 3 is 50 mm thick, the thickness of the jacket is 4 about 5 mm.

In the case of a medium transport line such as a district heating line, there is the problem that leaks have to be located. To that end is a sensor 5 or a sensor wire is provided with a for protection and insulation serving cover layer 6 is provided. The sensor 5 runs with the medium transport line 1 with and has a cover layer G, which consists of a material which at certain temperatures water with deterioration of its electrical properties th, in particular the ohmic and / or capacitive resistance. To this In this way it is possible to determine which one is by taking appropriate measurements Place water occurs in the medium transport line.

However, since - as mentioned - the cover layer 6 of the sensor 5 at certain If water absorbs temperatures, it can also be determined whether the water is warm from which: the inner pipe 2 emerges or, if the casing 4 is damaged, water from has penetrated the outside of the medium transport line 1. The sensor 5 can, as in Fig. 3 is shown schematically, from sensors 7. exist, which any May have three-dimensional shape. These sensors 7 are associated with one of those already described Cover layer provided corresponding cover layer 8, along the medium transport line 1 spaced and for pulse reflection measurement through an isolated Head 9, in Fig.

3 shown in dashed lines connected.

As is further shown in Fig. 1, the sensor 5, from a message leader 10 and a covering layer 6 surrounding it, a second Message headers 10a are assigned, which are also surrounded by a cover layer 6a is. If the two cover layers 6 and 6a of the message wires 10 and 10a are different Have temperature characteristics, it is possible through appropriate measurement results to get more detailed information about faults occurring in the district heating line. As shown in Fig. 1, the two message wires can be separated outside of the Inner tube 2 be arranged; but it is also possible to use the two message wires 10 and iOa, for example by stranding or as shown in FIG. 2 is shown.

The signal cable shown in Fig. 2 consists of the two signal wires 12 and 13. The reporting wire 12 has a cover layer 14 made of a first material Mistake. The message head 12 with the hbdpckschicht 14 and the message head 13 Silld both , e.1> insam ipil a covering layer 15 from a second> 'aterial provided, its physical properties depend on the material of the audeck layer 14 differ.

In a medium transport line 1 a shown in FIG. 3 the inner tubes 2 with their insulating layer 3 by webs 16 on a sloping The bottom 17 of a concrete channel 18 is arranged. The sensor 5 is at the lowest Place, in Fig. 3 in the lower right corner of the concrete channel 18, where the water must collect that either enters through the joint 19 of the concrete channel 18 from the outside or emerges from the inner tube 2.

As described, the sensor can consist of sensors with neutral insulated wires, e.g. full PTFE wires, are connected to one another, or the sensor consists of message wires or a message cable running along the transport line.

In Fig. 4 is a modified embodiment of a medium transport line lb shown. The inner tube 2 is covered with an insulating layer 3 made of rock wool, which surrounds an air-filled annular space 20. An outer steel jacket tube is located via webs 21 22 is supported on the inner tube 2 and closes the air ring space 20 from the outside. The sensor is located in the air ring space 20 at the lowest point of the medium transport line 1 5 arranged.

Since especially with a district heating line from the inner pipe 2 warm Water leaks and comparatively cold water from the outside into the medium transport line can occur, particularly meaningful measurements are possible to determine whether and, if so, there is a display of leaks in the routes of the transport pipeline , if with a sensor 5 the cover layer only with warm or cold water the Penetration made possible.

FIG. 5 shows a diagram in which the dependency the resistance versus temperature for two materials for the cover layer is shown. The lower curve PA relates to polyamide, while the approx Curve running from top left to bottom right relates to PU polyurethane. In an (1e7e1 As in the case of polyamide, water creates an Ilydrolysisvcrgeng in polyurethane, where the hydrolytic degradation by hot water, hot watery Solutions, saturated steam and hot, humid air is accelerated.

As the diagram according to FIG. 5 shows, polyamide is already at There is a low resistance at low temperatures, which also increases at higher temperatures Temperatures hardly changed, while with polyurethane with cold water or with Water at normal temperature shows a very high resistance, which is very strong at Heating of the water is broken down. Are the materials polyamide and polyurethane used for the cover layers 6 and 6a of the sensor 5 according to FIG. 1, so occurs in the case of cold humidity that enters the medium transport line from the outside, in the case of Sensor wire with the polyamide cover layer has a low resistance, with the sensor wire a high resistance with the polyurethane cover layer. However, warm moisture occurs from the inner tube 2, it is the same with the polyamide cover layer as with the polyurethane cover layer there was little resistance. This is also the case when the cold External moisture heats up after entering the transport line.

The medium transport line according to the invention thus enables in addition to the determination, location or display of leaks and the determination of whether through A leak on the inner pipe is causing moisture, i.e. whether, for example Water escapes from the inside or whether the fire enters the medium transport line from the outside has penetrated. The cover layer 6, 8 or 11 used is also a mechanically closed structure is achieved, and there is a risk of damage significantly reduced compared to the previously required perforation for the Water leakage that encouraged the damage. In addition to the mechanical Strength and the smooth surface are also thick layers of insulation with a To achieve the great insulating effect caused by this, or rather with the rchanlschen Perforation was not possible. Finally, there is also an increased accuracy of measurement There is a limit to the definability of the target level. . In case of Momentum reflectometry becomes an accurate, more meaningful momentum reflection achieved due to the changing wave resistance,! by changing the dielectric constant the cover layer made of polyurethane or polyamide on the sensor surface by recording of water changes. These advantages are achieved by attaching or laying the sensor is easier with a reduced risk of damage.

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Claims (12)

Claims 1. Medium transport line, in particular district heating line, with an inner tube used for transport and at least one outside the inner pipe, the monitoring and fault location the nenden sensors with a cover layer serving for protection and insulation, characterized that the cover layer (6, 8) of the sensor (5) consists of a material which at certain temperatures water with a change in its electrical properties, in particular the ohmic and / or capacitive resistance. 2. Transport line according to claim 1, characterized in that the cover layer (8) is applied to sensors of any spatial shape, which are spaced arranged along the line (fa) and for pulse reflection measurement by a insulated conductor (9) are connected. 3. Transport line according to claim 1, characterized in that the sensor (5) consists of at least one reporting wire (6) which r; lit the cover layer (10) is surrounded. 4. Transport cable according to claim 3, characterized in that the the message head (4iJ) has a cover layer (o j 1 which only covers when the water is warm allows a major (. ii penetration of water. 5. Transport line according to claim 4, characterized in that the cover layer (6) made of polyurethane, preferably polyurethane foam. 6. Transport line according to claim 3, characterized in that the message lead (10a) has a cover layer (6a) that is only used when the water is cold allows penetration of the water. 7. Transport line according to claim 6, characterized in that the cover layer (6a) consists of polyamide. 8. Transport line according to one of claims 3 to 7, characterized in that that two signaling wires (10, 10a; 12, 13) with cover layers (6, 6a; 14, 15) of different Temperature characteristics are provided. 9. Transport line according to claim 8, characterized in that the two signaling wires (10,10a) with cover layers (6, 6a) of different temperature characteristics are arranged separately outside the inner tube (2). 10. Transport line according to claim 9, characterized in that the two signaling wires (10, 10a; 12, 13) with cover layers (6, 6a; 14, 15) to one Signal cables are grouped together. 11. Transport line according to claim 10, characterized in that a reporting wire (12) is provided with a cover layer of a first material (14) and with a different message header (13j from a common cover layer (15) is enclosed from a second material. 12. Transport line according to one of claims 1 to 11, characterized in that that the sensor is below in the capillary (1 b) or in a tone channel (ia) with inclined floor (17) at the lowest point: is.