WO2020035179A1

WO2020035179A1 - Measuring system for classifying poles and method therefor

Info

Publication number: WO2020035179A1
Application number: PCT/EP2019/061272
Authority: WO
Inventors: Jürgen Grönner; Stefan Nykamp
Original assignee: Westnetz Gmbh
Priority date: 2018-08-14
Filing date: 2019-05-02
Publication date: 2020-02-20
Also published as: DE102018119679A1; EP3837751A1

Abstract

The invention relates to a measuring system for classifying poles of a supply network, in particular of a power supply network or a telecommunication network, comprising a measurement recorder, a fastening device designed to fasten the measurement recorder to the pole, a sensor arranged in the measurement recorder, which sensor is designed to capture at least one measured value, and a communication device arranged in the measurement recorder, which communication device is designed to transmit the measured value captured by the sensor to an evaluation device, at least the sensor and the communication device being self-powered. The evaluation device is designed to receive the measured value and at least one additional environmental parameter and outputs a characteristic value mechanically describing the pole in dependence on the measured value and the environmental parameter.

Description

Measuring system for classifying masts and methods therefor

The subject matter relates to a measuring system for classifying masts of a supply network, in particular an energy supply network or a telecommunications network, and a method for determining a characteristic value describing a mast.

Supply lines of a supply network, in particular one

Power supply network or a telecommunications network are laid both under the floor and over the floor. When laying above ground, the lines are usually stretched between masts. The masts are made in a wide variety of designs and from a wide variety of materials. However, all masts have in common that they are permanently exposed to the environment and are therefore exposed to a natural aging process.

This is of particular interest for wooden poles, as they can already rot after a few years due to weather processes. Also theirs

Anchoring in the foundation or in the ground can be damaged by wind loads and rain.

If a mast falls over, the supply network is damaged and a repair is associated with considerable effort. It is better to replace masts when they are still stable, because then a failure of the supply system can be avoided.

It is known that the vibration behavior of masts depends on their internal structure. A mast can be set in motion by an external stimulus. This vibration, especially the natural vibration of the mast, can be characteristic of the rigidity of the mast. The stability in the

The floor or the foundation can influence the natural vibration of the mast.

It is known to subject masts to a manual inspection. Here, a transducer with integrated vibration sensors is manually attached to the mast and the mast is excited manually. For example, a sledgehammer is used to strike the mast or to vibrate the mast with your hands. The sensor records the mast's impulse response to this external stimulus. The recorded impulse response can be evaluated and conclusions can be drawn about the stability, rigidity or other mechanical properties of the mast. However, manual inspection is time-consuming, so that masts are only inspected every few years. However, these large periods of time between individual inspections can be problematic, since the mast can be damaged in the meantime by weather influences or unreported accidents (e.g. with industrial trucks) that it can be knocked over by the wind.

A measuring system is therefore proposed which enables an automatic inspection of masts.

A concrete mast can be a wooden mast or a mast made of metal or concrete. A mast can also be a street lamp or a mast of one

Be a traffic light system. A mast can be a single mast or a double mast, with an L-boom or with a T-boom, with a concrete foundation or a simple ground drive.

Supply networks can be, in particular, energy supply networks, in particular electrical distribution networks, and also telecommunications networks, in particular based on copper lines or fiber optic lines. The measuring system includes a sensor with which mechanical measurements on the mast can be recorded. The system also includes a

Fastening device set up for fastening the sensor to the mast. The attachment is, for example, one

Fastening sleeve that can be placed around the mast.

The sensor is preferably fastened with the fastening device in an upper third of a mast. A distance from the floor is preferably more than 2.50 m, in particular more than 3 m, and a distance from the top of the mast is preferably between 20 cm and 50 cm. The distance from the floor ensures that sabotage on the sensor is difficult. The heel to the top ensures that there is no electrical flashover from, for example, an electrical line attached to the mast

Sensor can take place.

At least one sensor is provided in the sensor. This sensor is set up to record at least one measured value. The sensor is preferably a vibration sensor and / or an inclination sensor. With the help of the sensor, it is possible to record the vibration of the mast in an observation period. The signal determined from this is characteristic of the natural vibration of the mast depending on the external excitation, in particular an excitation by wind.

In order to ensure that an inspection of the mast can be automated and carried out remotely, there is one in the sensor

Communication facility set up. The communication device is, for example, a radio module, for example GSM, UMTS, LTE, 5G or the like. The communication device can also use a long range (LoRa)

Communicate radio protocol. The advantage of this LoRa technology is its very long range and low operating costs, which is made possible in particular by the low bandwidth of this protocol. Since the measured values recorded by the sensor have only a small data volume, one can in particular Radio technology can be used, which provides only low bandwidths, but at the same time a long transmission range at a high

Transmission security guaranteed.

It is also proposed for automated remote checking of the masts that at least the sensor and the communication device are self-powered. The sensor is free from a connection to one

electrical supply system.

The measuring system also includes an evaluation device for receiving the measured value and at least one environmental parameter. The environmental parameter can be, for example, a wind speed and / or a wind direction. An environmental parameter can also be a temperature. In addition, a

Environmental parameters can also be an amount of precipitation, snow depth or the like. The at least one environmental parameter is evaluated together with the measured value, and the evaluation makes the mast mechanical

descriptive value calculated. This evaluation can also be used as a comparison value for other series of measurements of other masts, so that abnormalities can be detected.

A characteristic value that mechanically describes the mast can be, for example, the

Stiffness, stability, density, elasticity or any other value with the help of which an estimate can be made as to whether a mast has to be replaced or not, since it is otherwise at risk of overturning.

As already explained, the sensor can be a vibration sensor. Such a sensor records in particular the natural vibration of the mast as a measured value. The mast vibrates due to an external stimulus. This vibration can be as

Natural vibration can be understood. According to one embodiment, it is proposed that the

An energy converter is arranged. With the help of this

The transducer can be supplied with energy from its own energy source. Therefore, the energy converter can be set up to convert kinetic energy or light energy into electrical energy.

In addition, the sensor can have an electrical memory, which is fed by the energy converter (generator).

The generator generates electrical energy, for example from wind energy,

Solar energy or the like.

In addition, at least one energy store, for example in the form of batteries or capacitors, for example supercaps, can be arranged in the transducer and store sufficient energy to run through a measurement cycle.

A measuring cycle can e.g. include the acquisition of sensor measured values over a period of, for example, 1 minute to 15 minutes and the subsequent transmission of the measured values via the communication device. Such a measuring cycle can take place after an interval has elapsed, for example monthly, quarterly or semi-annually.

The energy store can be designed such that it is charged by the generator after the interval has expired so that the measurement cycle can be run through. The generator for the energetic self-supply can be dimensioned such that it provides sufficient electrical energy, in particular in the summer months, in order to have the energy store charged with sufficient energy after an interval has elapsed, so that at least one measurement cycle can be carried out. In the winter months, for example, the energy may not be sufficient to go through a measurement cycle after an interval. However, this is unproblematic, since monitoring can only take place quarterly, semi-annually or annually, for example.

The energy converter can be set up so that it only works with certain

Provides sufficient electrical energy to store the electrical storage within an observation interval with sufficient electrical energy to carry out a measurement cycle. This can be, for example, a photovoltaic converter that is designed in such a way that it needs one or more days of sunshine in order to supply the memory with sufficient electrical energy that it can support a measuring cycle.

According to one exemplary embodiment, it is proposed that the evaluation device is arranged in the measurement sensor or that the evaluation device is spatially distant from the measurement sensor. In the event that

Evaluation device is arranged in the transducer, the

Evaluation device either include environmental parameters locally by means of suitable sensors or receive environmental parameters via the communication device. The characteristic value can be calculated in the evaluation device and transmitted to a remote control center via the communication device.

In the case of the transmission of the sensor measurement values, the evaluation device can also be spatially distant from the measurement value sensor. In this

Evaluation device can also be loaded environmental parameters and together with these a characteristic value can be calculated for each connected mast.

The communication device for wireless transmission is set up to transmit either the measured values or the specific characteristic value. The

Transmission can preferably take place wirelessly, for example via a

Cellular network or long range radio. LoraWAN, in particular, has proven to be advantageous as long-range radio, since this has a high range at long ranges Transmission security guaranteed. This is ensured by the fact that the bandwidth is small.

According to one embodiment, it is proposed that the

Communication device is set up for the wired transmission of the measured value, in particular that the transmission takes place via optical fiber. Fiber optic cables are often routed on masts of a supply network, in particular a telecommunications network. Thus, the lines of the supply network, which can be fiber optic lines, can also be used to transmit the measured value. Such a fiber optic line enables communication with a remote control center. Additional wiring is not necessary.

The at least one sensor arranged in the measurement sensor can in particular be an inclination sensor and / or an acceleration sensor. One or more sensors can be arranged in a sensor. To synchronize the measured values detected by the sensors, it is proposed that a timer be arranged in the measured value sensor. In particular, timers from different sensors are synchronized with one another. With the help of the timer it is possible that all in one sensor

Arranged sensors record their measured values at the same time. It is also possible that a time stamp is assigned to each measured value. This time stamp can be used to assign a measured value to an environmental parameter at this point in time or to compare series of measurements.

If measured values are recorded, environmental parameters can be recorded at the same time and also given a time stamp. For example, it is possible that wind information is known at almost any point in time at almost any location. By using the time information and time stamps, at least one measured value, preferably a plurality of measured values, can be determined, such as environmental parameters associated with this measured value, in particular the Wind was at that time. Thus, the measured value can be measured using the

Time stamps are set in relation to the environmental parameter.

The time stamp can be assigned to the measured value as soon as it is recorded. It is also possible for the communication device to assign a time stamp to the measured value. In addition, the communication device can also assign a serial number to the measured value. The measured value together with the time stamp and / or the serial number can then be transmitted by the communication device. It is also possible for the measured value to be transmitted without a time stamp and for the receiving center to assign the time stamp to the measured value at the time of reception. Since the transmission generally only takes a fraction of a second to a maximum of a few seconds, it may be sufficient to only save the time stamp at the time

Assign reception to the measured value. This ensures that a timer is not necessary in every sensor.

According to one embodiment, it is proposed that the

Communication device transmits a set of measured values. For example, it is possible for a series of measurements to record several measured values and for these measured values to be transmitted collectively as a set of measured values. A measured value can also be formed from a time course of the sensor signals.

Since the masts are usually spread out over a wide area, it is almost impossible to receive measured values from all relevant masts through a single central station. For this reason, it is proposed that a communication gateway receive measurement values from a plurality of measurement sensors via a first communication channel and transmit the received measurement values in a bundle to the evaluation device via a second communication channel. The respective

Communication gateways can be set up at strategically relevant locations so that they have good coverage of a certain spatial area and can therefore receive the measured values from a large number of measurement sensors. The communication gateways can then, for example, also be connected to an evaluation center by cable and forward the measured values received by them to the center. This enables a cost-effective transmission of the measured values of all sensors to a central office through a distributed infrastructure.

As already explained, the sensor should be protected against vandalism and, on the other hand, there should be sufficient distance from the lines of the

Supply network. For this reason it is proposed that the

Transducer is permanently arranged in an upper third of the mast at a distance from the supply lines arranged on the mast.

It goes without saying that the measured values depend on the external excitation of the mast. With different wind loads and wind directions, the measured values can be extremely different. In order to be able to describe the mast mechanically, the measured values must be related to the environmental parameters. In particular, the measured values are normalized on the basis of the environmental parameters, so that the descriptive characteristic value is independent of

Is environmental parameter. It is proposed that the evaluation devices receive at least one measured value and at least one environmental parameter as input variables and output the characteristic value describing the masts as the output variable.

Depending on the properties of the mast and other parameters, the vibration behavior of the mast changes. So it is possible that at same

Different masts show different vibration patterns in wind conditions, but these masts should be rated equally in terms of their stability. In order to be able to take into account the variables influencing the vibration behavior when evaluating the measurement results, the input variables include, in particular, weather data, a topography of the mast location, a type of mast, and a

Connection topology of the mast, a distance from the mast to a neighboring mast, a mast height and a date individually or in combination with each other. Weather data are especially wind speed and wind direction. A

For example, topography of the mast location can take into account how the

Is shaped around the mast. For example, if masts are in the slipstream of hills or in a path, they behave differently in the same wind conditions than masts that are arranged on a flat field. The type of mast can be, for example, the material of the mast, for example wood or steel, the type of construction, for example single or double mast, the anchoring,

describe for example with or without a foundation or the like. A

Connection topology of the mast can describe how many lines go from the mast. The tension of a line can also be relevant. The

Line cross sections and line weights carried by the mast may also be relevant. The angles of departure of the cables from the mast can also be relevant. It can also be relevant how far masts are apart. This can provide information about how the cables sag between the masts and thus act on the mast. Of course, a mast height can be relevant because higher masts represent a higher wind load than lower masts. A date can be relevant insofar as, for example, the ground is usually moist in winter and therefore gives the mast less grip than the same ground in summer. All of these input variables have an influence on the vibration behavior without influencing the rigidity or stability of the mast as such. Therefore, these input variables should be taken into account at least in part when evaluating the measurement data.

The input variables and the output variable can be taught in a neural network or examined with regression analyzes. For example, it is possible to calculate input values [measured values and parameters) from known masts, which have a stiffness or stability that has been rated as sufficient, and to calculate the calculated output variable with the known output variable [stiffness, stability, code number, etc.) to compare. The neural network can be taught in via feedback, so that in operation under Consideration of known input variables the output variable by the neural

Network can be calculated.

It is also possible to evaluate the mechanical properties of a mast in relation to other masts. For example, it is possible to use a plurality of measured values from different masts as input variables

To receive transducers and to determine a deviation of the measured value from the majority of the measured values for at least one of the measured values.

For example, masts that are set up at the same or similar locations and have the same parameters such as topography, type,

Topology, distance to the neighboring mast, mast height or the like can be combined in a common cluster. Measured values from all masts of the cluster, which were recorded at the same or a similar point in time, can be compared with one another and the mast (s) can be determined, the measured values of which are to a certain extent from the measured values of the other masts, in particular from an average of the measured values of the other masts.

In order to ensure that measured values can be assigned to environmental parameters correctly in time and / or that measured values from different masts can be assigned to one another, it is necessary that the measured values have a time stamp and that this time stamp has been created by synchronized timers. For this reason, it is proposed that the transducers receive a time standard and transmit measured values with a time stamp depending on the time standard.

As already explained, a temporal synchronization of the input variables is necessary in order to calculate the correct characteristic value. It is therefore proposed that the input variables are synchronized in time. Another aspect is a mast with a previously described measuring system.

Furthermore, one aspect is a method according to claim 21.

As already explained, a temporal analysis of the input variables is necessary. It is therefore proposed that the measured value be correlated at least with the environmental parameter over time.

It is also relevant to the mast location for the environmental parameter. For example, it is known to record and provide wind data for individual geographical positions. Masts can thus be assigned specific wind data depending on their mast location.

It is not absolutely necessary that the communication device of the

Transmit the measurement data proactively, it may also be possible that the measurement sensors are polled by an evaluation device. When querying the measurement data, for example, time information can be transmitted from the evaluation device to the remote measurement sensors. When this information is received, a measurement cycle can be started, which for example ends after a few seconds or minutes, and the result can be transmitted to the evaluation device immediately afterwards. The time information is used to record the data recorded during this measurement cycle

To provide a corresponding time stamp for the measured values.

The subject is explained in more detail below with reference to a drawing showing exemplary embodiments. The drawing shows:

1 shows a sensor;

2 shows a transducer arranged on a mast; 3 shows an arrangement of masts along a supply line;

4 different connection topologies of masts;

5 shows the learning of a neural network;

6 shows the clustering of measured values;

7 shows a measured value series of a measured value sensor.

1 shows a sensor 2 with a housing. In the housing there are an energy store 4, a processor 5, a sensor 6 and a

Communication device 8 arranged. Optionally, an evaluation device 10 can be arranged in the measurement sensor 2 or spatially separated therefrom. The transducer 2 also has a fastening collar 12 and an energy converter 14. The fastening collar 12 is the

Transmitter 2 captively fixed on a mast. On the

Energy converter 10 can convert solar energy into electrical energy and the energy store 4 can be charged in this way.

The communication device 8 communicates wirelessly, for example by means of a mobile radio network or LoRa, with the evaluation device 10. Wired communication is also possible, in which case in particular an optical fiber line which is arranged on the mast can be used.

2 shows the measurement sensor 2 on a mast 16. The mast 16 is a T-mast with supply lines 18 on both sides and a glass fiber line 20. The measurement sensor 2 is fastened in an upper third of the mast via the fastening collar 12. After installation, electrical energy is generated by the energy converter 14 and stored in the energy store 4. The energy store 4 is designed in such a way that it stores sufficient energy at least to carry out a measurement cycle in one measurement interval. However, the energy store 4 is preferably not dimensioned much larger, but in particular in such a way that exactly one measurement cycle per measurement interval is possible.

During a measurement cycle, the energy store 4 feeds the processor 5, which has a wake-up circuit and changes from a sleep mode to a wake mode after a measurement interval. During the sleep mode, the processor has only a low power consumption, in particular in the milliwatt range, so that the energy store 4 can keep the processor 5 in the sleep mode for an entire interval.

In the measurement interval, the processor 5 controls the sensor 6 in such a way that it records measured values. The sensor 6 is preferably an inclination sensor or a vibration sensor. The sensor 6 records the inclination and / or vibration of the mast 16 over a period of a few seconds to a few minutes. The time course of the oscillation is transferred to the communication device 8 as a signal. The communication device 8 can transmit this measured value to the

Transmit evaluation device 10 wirelessly or by wire.

The evaluation device 10 evaluates the measured value in such a way that, in combination with environmental data, it specifies a characteristic value with which the mast 16 can be qualified.

Parameters that can be used to normalize the measured values are, in particular, weather data, distances between masts, a topology of the mast location and the like, as already described above. 3 shows, by way of example, four masts 16 along a supply line 18. The masts 16 are at a distance 16a. On each mast 16 one

Wind speed and a wind direction 16b can be determined at a time. Each mast 16 can be assigned topographical information, for example whether trees 16c or hills 16d lie in the area of the mast 16 and in particular the orientation of these obstacles 16c, 16d relative to the mast 16. These environmental parameters 16a-d can be used to measure the measured values to

normalize.

In Fig. 3 it can be seen that the obstacles 16c, 16d,

Wind speeds 16b in certain wind directions on the central masts 16 can be lower than on the outer masts 16. Also, different wind directions can prevail on the masts, as is also shown in FIG. 3.

FIG. 4 shows how supply lines 18 can leave the mast 16 at different angles a. The direction of the angles can also be decisive for the vibration behavior of the masts 16.

5 shows the teaching of a neural network 22. For the masts 16, the characteristic values are known during teaching, in particular whether a mast is in order or not. For known actual weather data 24, which are available for each mast 16, using actual vibration data 26, the on the mast by a

Winging signal were recorded, a characteristic value is calculated by the neural network. The characteristic value output by the neural network 22 can be compared with the characteristic value known for the respective mast 16 and a specific deviation can be coupled back into the neural network. This teaching of the neural network 22 can be carried out for a wide variety of masts 16 with a wide variety of input variables, in each of which it is known whether the mast is okay or not in terms of its characteristic value. The result of the calculation of the neural network 22 can be compared with the actual characteristic value of the Mastes are compared and the neural network 22 are taught accordingly.

After teaching the neural network 22, it is possible for this for each mast 16 actual wind data 24 and other parameters as input variables (which were also taken into account when teaching), such as mast height, topology, mast spacing, mast type and the like, as described above, supply. Using these input variables and the previous training, it is possible for the neural network 22 to output a characteristic value for the mast 16, which indicates whether the mast is OK or not.

It is also possible, as shown in FIG. 6, to determine actual measured values and actual parameters in a data record 30 for a plurality of masts 16. The masts 16, for each of which there is a data record 30, can be compared with one another on the basis of the large number of data records 30. It is possible to use from the data records 30 of each mast that measured value that was recorded under roughly the same environmental conditions. An average over all masts 16 can then be calculated and the data record 32, which deviates from the average by a minimum value, for example, can be identified. A mast 16 can thus be identified from the large number of measurement results, which is different from the other masts and may have to be replaced.

It is also possible to record a series of measured values 34 for a mast 16. This series of measured values 34 can be recorded for a single mast 16.

Afterwards it is possible to measure values of the series of measurements which are the same

Environmental conditions have been recorded, compared with one another and checked whether the measured values have changed despite the same environmental conditions. If there is a significant change beyond a limit value, it can be concluded that something has changed on the mast 16. Depending on how

Is change, it can also be concluded that the mast 16 must be replaced. With the aid of the method in question, it is possible to carry out an automated remote inspection of masts.

LIST OF REFERENCE NUMBERS

2 sensors

4 energy storage

5 processor

6 sensor

8 communication device

10 evaluation device

12 cuff

14 energy converters

16 mast

18 supply line

20 glass fiber

16a mast spacing

16b wind direction

16c trees

16d hill

24 actual wind data

26 Actual measurement data

22 neural network

30 records

32 Identified data record

34 series of measured values

Claims

Patent claims

1. measuring system for classifying masts of a supply network,

in particular an energy supply network or one

Telecommunications network comprising:

a sensor,

a fastening device set up for fastening the

Sensor on the mast,

a sensor arranged in the measured value pick-up, for detecting at least one measured value,

a communication device arranged in the measurement sensor is set up to transmit the measured value detected by the sensor to an evaluation device, at least the sensor and the sensor

Communication device are energetically self-powered

characterized,

that the evaluation device is set up to receive the measured value and at least one additional environmental parameter and that the

Evaluation device depending on the measured value and the

Environment parameter outputs a characteristic value that mechanically describes the mast.

2. Measuring system according to claim 1,

characterized,

that the measured value includes the natural vibration of the mast.

3. Measuring system according to one of the preceding claims,

characterized, that on the transducer an energy converter, set up for

Conversion of kinetic energy or light energy into electrical energy and for electrically feeding at least the transducer with electrical energy is arranged.

4. Measuring system according to one of the preceding claims,

characterized,

that the evaluation device is arranged in the measurement sensor or that the evaluation device is arranged spatially distant from the measurement sensor.

5. Measuring system according to one of the preceding claims,

characterized,

that the communication device for wireless transmission of the

Measured value and / or the characteristic value is set up, in particular that the wireless transmission takes place via cellular network or long-range radio, in particular LoraWAN long-range radio.

6. Measuring system according to one of the preceding claims,

characterized,

that the communication device is set up for the wired transmission of the measured value, in particular that the transmission takes place via glass fiber.

7. Measuring system according to one of the preceding claims,

characterized,

that the sensor has an inclination sensor and / or a

Acceleration sensor and that the sensor records at least one, preferably all sensors at the same time a measurement.

8. Measuring system according to one of the preceding claims,

characterized,

that the communication device assigns a time stamp and / or a sequential number to the measured value and transmits the measured value together with the time stamp and / or the sequential number.

9. Measuring system according to one of the preceding claims,

characterized,

that the evaluation device assigns a time stamp and / or a serial number to the received measured value when the measured value is received.

10. Measuring system according to one of the preceding claims,

characterized,

that the communication device transmits a set of measured values.

11. Measuring system according to one of the preceding claims,

characterized,

that a communication gateway measured values from a plurality

Receives the measuring sensor via a first communication channel and transmits the received measured values in a bundle to the evaluation device via a second communication channel.

12. Measuring system according to one of the preceding claims,

characterized,

that the measuring sensor is permanently arranged in an upper third of the mast at a distance from the supply lines arranged on the mast.

13. Measuring system according to one of the preceding claims,

characterized, that the mechanical value describing the mast includes a rigidity of the mast.

14. Measuring system according to one of the preceding claims,

characterized,

that the evaluation device receives at least one measured value and at least one environmental parameter as input variables and outputs the characteristic value mechanically describing the mast as output variable.

15. Measuring system according to one of the preceding claims,

characterized,

that input variables are in particular weather data, a topography of the mast location, a type of mast, a connection topology of the mast, a distance from the mast to a neighboring mast, a mast height, a date.

16. Measuring system according to one of the preceding claims,

characterized,

that the input variables and the output variable are learned in a neural network.

17. Measuring system according to one of the preceding claims,

characterized,

that the evaluation device provides a plurality of input variables

Receives measured values from measuring sensors arranged on different masts and determines a deviation of the measured value from the majority of the measured values for at least one of the measured values.

18. Measuring system according to one of the preceding claims,

characterized,

that the measured value recorders receive a time standard and transmit measured values with a time stamp depending on the time standard.

19. Measuring system according to one of the preceding claims,

characterized,

that the input variables are synchronized in time.

20. Mast with a measuring system according to one of the preceding claims.

21. Method for determining a characteristic value describing a mast in which:

at least one measured value is measured by a measured value pickup on a mast, the recorded measured values are transmitted to an evaluation device, the evaluated measured value is evaluated in the evaluation device together with at least one environmental parameter and the characteristic value is determined depending on the evaluation.

22. The method according to claim 21,

characterized,

that during the evaluation the measured value is correlated with the environmental parameter.

23. The method according to any one of the preceding claims,

characterized,

that the measured value and the environmental parameters are evaluated as input variables of a neural network and that the characteristic value is output by the neural network.

24. The method according to any one of the preceding claims,

characterized,

that a plurality of masts are combined in a cluster, the cluster depending on at least one mast height, a topography of the mast location, a type of mast, a connection topology of the Mast and / or a distance of the mast to a neighboring mast and the measured values are compared in a cluster for evaluation.

25. The method according to any one of the preceding claims,

characterized,

that the environmental parameters are assigned to a measured value depending on a mast location.

26. The method according to any one of the preceding claims,

characterized,

that measured values are polled by a measuring sensor through the evaluation device.

27. The method according to any one of the preceding claims,

characterized,

that the energetic self-supply of the sensor is such that a measurement and transmission of the measured value are at least one day apart.