DE102011122132A1 - Inductive loop line - Google Patents

Abstract

In an induction loop line (1) with at least one electrical conductor (12) and at least one insulation (13), the line (1) has at least one tractive force-absorbing stretchable part (10, 11, 13) to avoid failures under tensile stress. In a line failure monitoring device using such an induction loop line (1), the device comprises means (20) for monitoring the resistance of the tensile force-receiving stretchable part (10) of the induction loop line (1) and means for detecting an electrical breakdown by a Insulation (15) of the expansible part (10) of the induction loop line (1) or means (21) for determining the insulation thickness (s15) of the insulation (15) surrounding a blind conductor (11) of the core element (10) of the expansible part (10) ).

Description

The invention relates to an induction loop line with at least one electrical conductor and at least one insulation.

Induction loops are usually arranged in lanes, for example, they serve to detect the presence of vehicles in front of a traffic light, for speed detection or other traffic monitoring. An induction loop is usually traversed by alternating current, which generates an oscillator. Frequency determining is the loop inductance in connection with the supply line. The loop current leads to an alternating magnetic field, which generates eddy currents in the metal parts of a vehicle located above the induction loop, which in turn influence the alternating field, so that the loop inductance decreases. This leads to an increase in the loop frequency. The change in the loop inductance thus serves to detect the vehicle and is detected by a detector.

As problematic it has been found that roads or the road surface can partially sag over time, so that there is a difference in height in the field of laying the induction loop line. As a result, the induction loop line is subjected to a tensile stress, which can lead to a reduction of the conductor cross-section up to a crack of the line, thus to their uselessness and failure.

The present invention is therefore based on the object to provide an induction loop line in which the negative effect of a conductor cross-section reduction, ie a failure of such a line can be avoided as possible. Furthermore, the present invention also has the object of detecting a change in the road surface or a road surface as early as possible in order to avoid a line failure.

The object is achieved for an induction loop line according to the preamble of claim 1, characterized in that the line to avoid failures under tensile stress has at least one tensile force-absorbing stretchable part. For a device for line failure monitoring using an induction loop line, the object is achieved in that the device comprises means for monitoring the resistance of the tensile force-receiving expansible part of the induction loop line and means for determining an electrical breakdown by insulating the expansible part of the induction loop Comprises a conduit or means for determining the insulation thickness of the insulation surrounding a stub conductor of the core element of the expansible member. Further developments of the invention are defined in the dependent claims.

As a result, an induction loop line is provided, which can compensate for a tensile stress due to their at least partial stretchability or extensibility, since the at least one tensile absorbing elastic part absorbs them and thus the at least one conductor is not or at least over a long distance away no longer the risk of Tearing is subject and thus line failures can be avoided. Tensile stress is absorbed by the provision of the extensibility of the at least one portion of the induction loop conduit, thus maintaining the operability of the conductors and conduit.

Advantageously, the at least one conductor is coupled to the expansible part in such a way that a tensile stress is absorbed by the lay length of the conductor. Upon application of a tensile force on the line, the stretchable part expands and the lay length of the conductor increases.

Further advantageously, the stretchable part comprises a stretchable with respect to the line centrally arranged core element. Particularly advantageous is the stretchable centrally arranged core element is a plastic element. In particular, this consists of PTFE, so polytetrafluoroethylene. It can, for. B. be formed in the form of a plastic cord. This stretchable central element arranged centrally in the conduit can stretch under tensile stress, thereby reducing or tapering its diameter and increasing its length.

The stretchable part, in particular the stretchable centrally arranged core element, may be surrounded on its outside by a number of conductors. These are advantageously around the stretchable part, in particular the stretchable centrally arranged core element, stranded around. In this way, a destruction of the conductors, which consist in particular of copper, can be avoided, since the diameter of the expansible part or of the stretchable centrally arranged in the line core element is reduced in an action of a tensile force on the induction loop line, this is the lay length of this or this surrounding conductor increases, without the conductors themselves being loaded on train, which would reduce their diameter or they would be rejuvenated. Thus, a wire break due to tensile load of the induction loop line can be effectively avoided. Furthermore, the electrical properties of the induction loop line do not change over a wide range, since only the stretchable part or the stretchable centrally disposed in the line core element is loaded, but not the surrounding conductors of the induction loop line.

As further advantageous, it proves to provide the at least one conductor surrounding an insulation. This insulation, which may consist of one or more insulation layers, serves to insulate and also protect the outer conductor. For outside mechanical and thermal protection of the conductor, the line may be surrounded on the outside by a braid, in particular a mesh of impregnated glass fibers. By providing such a braid on the one hand, external protection against damage is given, above all, while a tar cover is applied to the induction loop line as the outer layer of a roadway. On the other hand, a flexibility of the line is given, which can be provided by the provision of impregnated glass fibers in addition to the mechanical and thermal protection, a special stability of the outer sheath of the line. This proves to be very advantageous because of the arrangement in a road surface not only in the manufacture of the same, but also in operation, since the mechanical stresses of such an induction loop line can be high by driving overhead vehicles and environmental influences.

By way of example, the nominal cross section of the conductor which surrounds the expansible core element arranged centrally in the line can be 1 to 2 mm ² , in particular 1.5 mm ² . The resistance of the conductors can be, for example, a maximum of 13 Ω / km.

The stretchable part of the induction loop line can be further advantageously used for monitoring purposes with regard to the change of the road surface or in the area of the induction loop line. The core element may include an inner blind conductor for monitoring a line failure. As a blind conductor, for example, a copper conductor is suitable. This is advantageously embedded in the core element, so that the material of the core element serves as insulation of the blind conductor, so that it is designed as a core wire. If the induction loop line is subjected to tensile stress, the stretchable part, in particular the elastic core core arranged centrally in the line, expands, thereby tapering as it lengthens and its resistance thereby increases. Depending on the resistance of the stretchable part or the center core arranged in the core, the amount of strain can be determined. This is possible via an evaluation device which interrogates the means for monitoring the resistance of the expansible part or the stretchable core wire of the induction loop line arranged centrally in the line and calculates the elongation on the basis of the resistance values determined. In addition, through the means for detecting an electrical breakdown by isolating the expansible portion of the induction loop line, the operability of the induction loop line can be monitored. Instead of providing the means for monitoring an electrical breakdown by the insulation of the blind conductor and means for determining the insulation thickness of the blind conductor surrounding insulation can be provided. Based on the information concerning the thickness of the insulation surrounding the stub conductor of the line, the risk of electrical breakdown can be deduced. A corresponding evaluation can be carried out in an evaluation unit. This can give early warning of a threat of electrical breakdown or forward to a corresponding signaling device that outputs the warning message. The evaluation unit can thus carry out the evaluation with regard to an imminent failure of the induction loop line based on the information relating to the electrical resistance of the expansible part, or on the information relating to the thickness of the insulation of the blind conductor. If an evaluation determines that the resistance of the stretchable part increases and / or the thickness of the insulation of the dummy conductor assumes too low value, so due to the tensile stress it comes to a reduction of the insulation layer thickness, is an electric breakdown to be feared and it gives a corresponding Warning message from or to the signaling device from. Thus, early the risk of line failure of the induction loop line can be detected because early changes in the road surface or the road surface, in which the induction loop line is arranged, determined and possibly an exchange of the induction loop line can be made early.

For further explanation of the invention embodiments of this will be described in more detail below with reference to the drawings. These show in:

1 a cross-sectional view of a first embodiment of an inventive induction loop,

2 a sketchy side view of the induction loop line according to 1 and

3 a cross-sectional view of a second embodiment of an induction loop line according to the invention.

1 shows a cross-sectional view of an induction loop line 1 , This includes a stretchable center in the pipe 1 arranged core element 10 , two layers of electrical conductors 12 on the core element 10 and an insulation layer 13 that the ladder 12 surrounds. The outside is the line 1 from a mesh layer 14 surrounded or encased. This can for example have impregnated glass fibers.

The middle in the pipe 1 arranged, expandable core element 10 For example, it is made of PTFE (polytetrafluoroethylene) or another polymer material. It has z. B. a maximum diameter of 0.8 mm. Also the insulation layer 13 can be made of PTFE. For example, it has a layer thickness of 0.45 mm. The nominal cross section of the conductors 12 holding the elastic centered in the pipe 1 arranged core element 10 surrounded, for example, 1 to 2 mm ² , in particular 1.5 mm ² .

The electrical conductors 12 consist for example of copper. In the in 1 30, such copper conductors or wires are saponified around the core element 10 arranged around in two layers. The on the kernel element 10 arranged location includes 12 conductors 12 , the second location 18 ladder 12 , In principle, it is also possible here more or less head 12 around the centrally arranged core element 10 to arrange around or even provide an arrangement in more than two layers.

How out 1 can be seen, leads to a tensile stress of the core element 10 in the longitudinal direction to a reduction of the diameter d _{10 of} the core element 10 , Because of the better in 2 to see the stranding in the middle of the pipe 1 arranged core element 10 surrounding conductor 12 carries a tensile stress F _z on the line 1 only to increase the lay length S of the ladder 12 , where in 2 the enlarged lay length is indicated by dashed lines and denoted by S ', but not to an elongation or taper of the ladder 12 , The resistance and other electrical properties of the induction loop line 1 thus remain the same over a wide range of traction. Only with excessive tensile stress can it also be a change in the electrical properties of the line 1 come.

The change of the diameter of the central core element 10 under tensile load can also lead to line failure monitoring or to monitor the change of the road surface / the road surface, in the / the induction loop line 1 is inserted. For this purpose, as in 2 shown is the core element 10 modified. This includes a blind conductor 11 at the center of the line 1 that of an isolation layer 15 is surrounded. It is therefore a core wire instead of the provided without a conductor core element 10 intended. The blind conductor 11 can z. B. made of copper. To the insulating layer 15 around are, as in the embodiment 1 and 2, the ladder 12 stranded arranged. The arrangement can be as in 2 indicated. The resistance of the dummy conductor 11 increases under tensile stress with a corresponding reduction in its diameter, so that a query of the resistance by the in 3 indicated measuring device 20 of the centrally arranged blind conductor 11 can be determined whether it is stretched due to excessive tensile stress, so lengthened.

Furthermore, the thickness or layer thickness s _{15 of} the insulating layer 15 through a measuring device 21 be monitored. When applying a tensile force on this, the layer thickness s _{15 of} the insulating layer is reduced 15 also. From a certain minimum layer thickness there is an electrical breakdown. In order to be able to detect this prematurely, monitoring of the resistance of the blind conductor can be carried out 11 and the layer thickness s _{15 of} the insulation layer 15 early a significant tensile stress of the induction loop line due to changes in the road surface / the pavement, in which it is arranged by a in 3 merely indicated evaluation unit 22 determined and thus made an early required replacement of the induction loop line.

In addition to the above-mentioned and shown in the drawings embodiments of an induction loop line and a device for line failure monitoring many more can be formed in which each line to avoid failures under tensile stress has at least one tensile force-absorbing stretchable part or at least partially stretchable is formed, in particular has a stretchable centrally arranged in the line region, which does not serve the electrical line and the electrical conductors are arranged around it.

LIST OF REFERENCE NUMBERS

1

Inductive loop line

10

stretchable centrally located in the line core element

11

electrical blind conductor

12

electrical conductor

13

insulation layer

14

braided layer

15

insulating

20

Measuring device for determining the resistance of the blind conductor

21

Measuring device for determining the thickness of the insulation layer 15

22

evaluation

d ₁₀

Diameter of the core element

₁₁

Diameter of the dummy conductor

s ₁₅

Layer thickness of the insulation layer 15

S

Lay length of the ladder

S '

increased lay length of the ladder under tensile stress

Claims (11)

Induction loop line ( 1 ) with at least one electrical conductor ( 12 ) and at least one insulation ( 13 ), characterized in that the line ( 1 ) to avoid failures under tensile stress at least one tensile force-absorbing stretchable part ( 10 . 11 . 13 ) having. Induction loop line ( 1 ) according to claim 1, characterized in that the at least one conductor ( 12 ) to the stretchable part ( 10 . 11 ) is coupled so that a tensile stress by the lay length (S) of the conductor ( 12 ) is intercepted. Induction loop line ( 1 ) according to claim 1 or 2, characterized in that the stretchable part ( 10 . 11 ) a stretchable with respect to the line ( 1 ) centrally arranged core element ( 10 ). Induction loop line ( 1 ) according to claim 3, characterized in that the stretchable centrally arranged core element ( 10 ) is a plastic element, in particular consists of PTFE .. Induction loop line ( 1 ) according to claim 3 or 4, characterized in that the stretchable part, in particular the stretchable centrally arranged core element ( 10 ), on its outside of a number of ladders ( 12 ) is surrounded. Induction loop line ( 1 ) according to claim 5, characterized in that the conductors ( 12 ) around the stretchable part, in particular the stretchable centrally arranged core element ( 10 ), are stranded around. Induction loop line ( 1 ) according to one of the preceding claims, characterized in that the at least one conductor ( 12 ) surrounding an insulation ( 13 ) is provided. Induction loop line ( 1 ) according to one of the preceding claims, characterized in that the line ( 1 ) on the outside of a mesh ( 14 ) is surrounded, in particular a network of impregnated glass fibers. Induction loop line ( 1 ) according to one of claims 3 to 8, characterized in that the nominal cross-section of the stretchable centered in the line ( 1 ) core element ( 10 ) surrounding conductor ( 12 ) 1 to 2 mm ² , in particular 1.5 mm ² , is. Induction line ( 1 ) according to one of the preceding claims, characterized in that the core element ( 10 ) an inner blind conductor ( 11 ) for monitoring a line failure. Device for line failure monitoring using an induction loop line ( 1 ) according to one of the preceding claims, in particular according to claim 10, characterized in that the device means ( 20 ) for monitoring the resistance of the tensile force-absorbing stretchable part (FIG. 10 ) of the induction loop line ( 1 ) and means for determining an electrical breakdown by insulation ( 15 ) of the stretchable part ( 10 ) of the induction loop line ( 1 ) or means ( 21 ) for determining the insulation thickness (s ₁₅ ) of the one dummy conductor ( 11 ) of the core element ( 10 ) of the stretchable part ( 10 ) surrounding insulation ( 15 ).

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