EP1880225A2

EP1880225A2 - Method for determining the condition of a long body

Info

Publication number: EP1880225A2
Application number: EP06777205A
Authority: EP
Inventors: Hermann Koch
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2005-05-09
Filing date: 2006-04-20
Publication date: 2008-01-23
Also published as: DE102005022180A1; US20080157785A1; CN101171523A; WO2006120112A2; WO2006120112A3

Abstract

The invention relates to a long body, for example a gas-insulated electric line (1), the condition of which is tested by an electronic signal that is supplied to said body and can be received by a receiver unit. The electronic signal has a predefined duration and form. According to the method, the receiver unit receives signals, evaluates them in terms of duration and/or form and identifies said signals as the supplied signals or discards them as interference signals.

Description

description

Method for determining the state of a spatially extended body

The invention relates to a method for determining the state of a spatially extended body, wherein wel ^¬ chem an electronic signal is fed into the body and which is receivable by a receiving device.

It is known to feed an electrical signal into the tube for diagnosing a corrosion protection coating, for example of pipes, and to detect this electrical signal by means of a receiving device. Depending on the state of the anticorrosive coating, a more or less strong or changed in its shape signal can be received. From the received signals can then be concluded on the condition of the anti-corrosion coating.

In spatially extended bodies, such as long pipe sections, a superposition by interference is hardly avoidable. These interfering signals make it difficult to identify the ^injected electrical signal.

The object of the invention is to provide a method by which a more reliable determination of the state of a spatially designed body is made possible.

This is achieved in a method of the type mentioned above in that the electronic signal has a predetermined time duration and shape that the receiving device receives signals and in terms temporal duration and / or shape evaluates and identified as fed signal or rejected as interference signal.

By the predetermined time duration or the predetermined shape, the electronic signal can be clearly identified. Noise can be easily selected and discarded by the receiving device. Thus, an evaluation is restricted to the electronic signals of interest. As a result, the accuracy of the method is increased since disturbance variables are excluded from further considerations from the outset.

Both electrical signals and digital signals can be used as electrical signals. The signals kön- NEN this typical curve shapes, such as sinusoidal shaped ^¬ vibrations of a certain frequency, saw-tooth or certain pulse sequences have.

An advantageous embodiment of the invention may further provide that the electronic signal is cyclically repeatedly fed.

A cyclic repetition of feeding of the electronic signal ^¬ rule offers the advantage that a plurality of signal sequences can be detected and thus an improved diagnostic capability is provided. Thus, for example, it can be provided that a selection of the most characteristic signals is made from a plurality of received electronic signals, so that a further improvement of the quality of the method can take place even at this stage. As electronic sig ^¬ nal identified, but overlaid with certain disorders electronic signals can be excluded as a further Be ^¬ trachtung. Furthermore, through the cyclic repetition of the electronic signal in addition to the time duration and / or the shape of the signal and the repetition cycle can be used as an identification feature.

It may also be advantageously provided that electronic signals of different durations and different forms are fed.

When applying the method in areas in which the electronic signal is subject to greater interference, it is advantageous to feed various electronic signals in the spatially extended body. By changing between different forms of electronic signals, an additional distinguishing criterion for the receiving device can be created. Thus, for example, it can also be provided that a sequence of different electronic signals with different time durations and different shapes is transmitted cyclically repeatedly. This sequence is then receivable by the receiving device and allows a higher detection probability ^¬ even with stronger disturbances. It can be provided that the sequence of different electronic signals is sent cyclically repeated. In this case, it can furthermore be provided that the receiving device constantly detects different forms of electronic signals and automatically searches for further electronic signals in certain forms and of specific time durations when recognizing individual signals. The cyclic repetition can also be detected automatically by the receiving device. By this automatic operation of the receiving device, this can be used with different transmitting devices. A synchronization or tuning of transmitting and receiving device therefore only needs within a certain frame to be done. The receiving device only has to be able to also receive the signals emitted by a transmitting device. A restriction to a certain frequency band or to a certain form is not necessary.

Advantageously, it can further be provided that an insertion and / or a suspension time of the electronic signal is set by using a count pulse emitted by a satellite located on an earth orbit.

In Earth orbits there are satellites that emit various counts that are receivable from corresponding devices. Because of these counts, it is possible to synchronize very precise time and counting operations. These counts can be received worldwide and have sufficient accuracy for carrying out the method according to the invention. Regardless of the location of the transmission ^¬ device of the electronic signal can be done so a very accurate generation of the electronic signal. As well as the necessary transmitting device and the receiving device can receive the counts of the satellite and make a synchronization. Thus, the transmitting and receiving device to a timing system of the same quality. This prevents measurement errors. The electronic signal sending device and the electronic signal receiving device move within the same time measuring system with the same error deviation.

In the following an embodiment of the invention will be explained in more detail and shown schematically in figures.

It shows the Figure 1 a spatially extended body to be examined and the

Figure 2 different electronic signals.

In the figure 1 acting as a spatially extended body gas-insulated electrical line 1 is shown. The gas-insulated electrical line 1 has a tubular outer jacket, which is provided with a corrosion protection coating. The outer jacket encloses an electrical conductor which is mounted in an electrically insulated manner. The interior of the outer jacket of the gas-insulated electrical line 1 is filled with an insulating gas under increased pressure. In the example shown in FIG. 1, the gas-insulated electrical line 1 is laid underground. However, al ^¬ tively are also other types of installation, such as within a body of water or inside a tunnel, possible. At inspection shafts 2 a, 2 b access to the outer jacket of the gas-insulated electrical line is possible.

By means of a transmitting device 3, an electronic signal can be fed into the outer jacket of the gas-insulated electrical line 1. The outer jacket of the gas-insulated electrical l 1 is formed for example of an electrically conductive material. Within the outer jacket, the injected electronic signal spreads. A corrosion protection coating on the outer jacket prevents the signal from the jacket from passing into the surrounding soil. Only minor leakage currents can pass through the corrosion protection coating. If damage occurs to the anticorrosive coating, penetration of the signal through the corrosion coating is enabled. To such flaws too detect, a receiving device 4, for example, equipped with a probe 5, which is contactable with the soil kon- tactile. By means of a display instrument 6, in ^¬ example, a potentiometer, the electronic signal is more or less strongly depictable depending on the state of the anti-corrosion coating.

By the display instrument 6, for example, stray noise could be displayed in the ground. In order to exclude this, the transmitting device 3 has a receiving device for receiving counts of a satellite located in an earth orbit. By means of the counting pulses, the electronic signal emitted by the transmitting device 3 can be synchronized, that is, the insertion or the suspension of the electronic signal can take place at exact times. As a result, on the one hand, the duration of the signal is influenced, on the other hand, in a cyclic repetition, the sequence time between two repetitions is determined.

Like the transmitting device 3, the receiving device 4 is equipped with such a receiving device, so that synchronization with the counting pulses of the orbiting satellite can also take place at the receiving device 4. This ensures that both the transmitting device 3 and the receiving device 4 operate within the same time system and the transmission or reception of the signal can be carried out, for example, to a microsecond exactly. Due to such a high resolution of the time sequence of the electronic signals, a reliable identification of the signals fed by the transmitting ^device 3 is given by the receiving device 4. In the figure 2 different signal waveforms are shown by way of example. At the time ti, the insertion of a signal by the transmitting device 3 is provided in each case. At the time t ₂ , the suspension of the signal is provided in each case. Between the time t ₂ and the time t ₃ , a so-called sequence time is provided in each case. After the expiry of the time sequence, a signal can be fed once again into the jacket of gasiso ^¬ patterned electrical conductor. 1 It can be provided that the signals shown in the diagrams of Figure 2 are each cyclically sent one after the other cyclically or find combinations of different signal sequences use. A combination of the different signal forms offers the advantage that a typical cyclically recurring image is generated, which can be identified by the receiving device 4 in a simple manner. This makes it possible to distinguish the electronic signal fed by the transmitting device 3 from interference signals.

Claims

claims

1. A method for determining the state of a spatially extended body (1), in which an electronic signal is fed into the body and which is receivable by a receiving device (4), characterized in that the electronic signal a predetermined time duration as ^¬ form in that the receiving device (4) receives signals and evaluates them with regard to temporal duration and / or shape and identifies them as a fed-in signal or rejects them as an interference signal.

2. Method according to claim 1, characterized in that the electronic signal is repeatedly fed in cyclically.

3. Method according to claim 1 or 2, in which electronic signals of different time duration and of different forms are fed in.

4. The method according to any one of claims 1 to 3, characterized in that an insertion and / or a suspension time (ti, t ₂ ) of the elekt ^¬ ronic signal is set using a sent from a satellite located on an earth orbit counting pulse.