EP2810255A1 - Procédé pour le pronostic d'une erreur ou pour la détection d'une erreur dans une machine de transport ainsi que machine de transport - Google Patents

Procédé pour le pronostic d'une erreur ou pour la détection d'une erreur dans une machine de transport ainsi que machine de transport

Info

Publication number
EP2810255A1
EP2810255A1 EP13713819.4A EP13713819A EP2810255A1 EP 2810255 A1 EP2810255 A1 EP 2810255A1 EP 13713819 A EP13713819 A EP 13713819A EP 2810255 A1 EP2810255 A1 EP 2810255A1
Authority
EP
European Patent Office
Prior art keywords
transport machine
error
detection
detection values
electrical system
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP13713819.4A
Other languages
German (de)
English (en)
Inventor
Markus SCHÄTTIN
Michael Armbruster
Thomas Schmid
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Siemens AG
Original Assignee
Siemens AG
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Siemens AG filed Critical Siemens AG
Publication of EP2810255A1 publication Critical patent/EP2810255A1/fr
Withdrawn legal-status Critical Current

Links

Classifications

    • GPHYSICS
    • G07CHECKING-DEVICES
    • G07CTIME OR ATTENDANCE REGISTERS; REGISTERING OR INDICATING THE WORKING OF MACHINES; GENERATING RANDOM NUMBERS; VOTING OR LOTTERY APPARATUS; ARRANGEMENTS, SYSTEMS OR APPARATUS FOR CHECKING NOT PROVIDED FOR ELSEWHERE
    • G07C5/00Registering or indicating the working of vehicles
    • G07C5/008Registering or indicating the working of vehicles communicating information to a remotely located station
    • GPHYSICS
    • G07CHECKING-DEVICES
    • G07CTIME OR ATTENDANCE REGISTERS; REGISTERING OR INDICATING THE WORKING OF MACHINES; GENERATING RANDOM NUMBERS; VOTING OR LOTTERY APPARATUS; ARRANGEMENTS, SYSTEMS OR APPARATUS FOR CHECKING NOT PROVIDED FOR ELSEWHERE
    • G07C5/00Registering or indicating the working of vehicles
    • G07C5/08Registering or indicating performance data other than driving, working, idle, or waiting time, with or without registering driving, working, idle or waiting time
    • G07C5/0808Diagnosing performance data

Definitions

  • the invention relates to a method for detecting errors, in particular to a method for the early prognosis of an error.
  • an associated transport machine should be indicated, e.g. a vehicle, an airplane or a ship.
  • the invention relates to a method for forecasting an error in a transport machine, comprising:
  • the invention relates to a transport machine, with:
  • a vehicle electrical system containing at least two parts, a separating device arranged between the at least two parts, with which the two parts can be electrically separated from each other,
  • a control unit which is connected to the separating device or with a warning unit, and which controls the separating device or the warning unit depending on the detected values detected by the detection device.
  • a transport machine is to be specified, which is particularly suitable for the application of methods with error prognosis.
  • One embodiment relates to a method for forecasting an error in a haulage machine, comprising:
  • the difficulty in forecasting errors consists, for example, in determining characteristic features which occur field of error, for example, would lead to the triggering of other safety devices. At a minimum, there should be a high probability between the occurrence of the feature and the occurrence of the error. If the probability is 100 percent, then there is a 1: 1 relationship or a deterministic or direct relationship.
  • the characteristic feature occurs, for example, only after several years of operation. If it then succeeds in associating an error with a characteristic feature from data that has been stored for a long time, this characteristic feature can be used in the vehicle repaired after the fault and, above all, in other vehicles of the same type for the early detection or prognosis of errors. This is possible by changing the operating software in a simple way, for example. In a workshop or via a wireless network.
  • the detection values can be stored. Alternatively, however, frequency spectra of the detection values are stored in order to reduce the amount of data, for example by a factor smaller than 10. Older data can also be erased or canceled out. For example. Deletes data older than one year. In the case of multiple storage per month, after the expiration of a period of time which, for example, is one month and one year, for out-of-period months only one record is stored for each month. Thus, data that has already been acquired and stored before the occurrence of a major error is used to determine the characteristic feature for the early detection of the error or for error detection. For example, data older than one day, older than one week, older than one month, or even older than one year may be used relative to the day the larger error occurred.
  • the detection values can be detected at a vehicle electrical system of the first transport machine.
  • early detection is particularly important because, for example, the power and voltage supply for important units must be secured. Faults in on-board networks can quickly lead to particularly serious errors, e.g. to fires.
  • the discharge of a battery can be prevented by the early detection of errors.
  • This can increase the acceptance of electric cars considerably, because they rely on a charged battery for driving.
  • the method can be carried out for a large number of vehicles, for example also for all vehicles of a manufacturer.
  • the database can be chosen as large as possible, since it is initially unknown in which vehicle the errors will occur.
  • a relevant sample is used. If characteristics for early detection or error detection have then been determined on the basis of the random sample, these features can also be used in predicted vehicles for prognosis, in particular in vehicles that did not belong to the random sample.
  • a wide frequency range can be detected in the spectrum, for example a frequency range which records more than 4 or more than 5 orders of magnitude.
  • a frequency range can be used, for example from 0 Hz to 10 MHz (megahertz) or even up to 100 MHz.
  • the largest frequency may typically be less than 1 GHZ. But even 50% or 80% of these ranges can be sufficient, especially if the percentages contain the upper frequency range. Again, it is not known or difficult to estimate where features change. Thus, a wide range ensures that changes are actually recorded.
  • the acquisition of the detection values can take place on a physically existing vehicle / transport machine or on a physically existing subsystem of the vehicle / transport machine or in a simulation of the first transport machine or a simulation of a part of the first transport machine.
  • a probability measure may be determined that indicates the probability of early detection of the error correct is.
  • An error which can not be detected without the stored detection values or the stored frequency spectra can be specifically incorporated into a part of the transport machine or into a simulation of at least part of the transport machine.
  • the insulation of a cable can be selectively thinned.
  • a cable can be heavily loaded mechanically, for example by pressure, by kinking or by pulling. As a result of the load on the cable, it may then come after a certain time to larger errors, such as cable break or short circuit.
  • an aging of the insulation could be simulated or a higher temperature, which reduces the insulation capacity.
  • the detection values or the frequency spectra can be stored outside the transport machine.
  • a transmission via radio or a reading during maintenance e.g. in a factory.
  • the proposed method can be carried out inexpensively with M2M (Machine to Machine) methods, e.g. via existing radio networks or via specially designed radio networks.
  • M2M Machine to Machine
  • an existing mobile network could be used, such as UMTS (Universal Mobile Telecommunications System) or LTE (Long Term Evolution).
  • the acquisition values or the spectra are collected for several transport machines, eg for more than 10, for more than 100 or for more than 1000 transport machines.
  • a database can be created for the vehicles of a vehicle type of a manufacturer or for all vehicles of a manufacturer with the same on-board networks.
  • the detection values or the spectra are also stored in the transport machine, for example in order to avoid transmission via public radio networks or to design them effectively, for example the data is transmitted only on a monthly basis.
  • a current profile or a voltage profile or both a current profile and a voltage profile can be detected. If both current and voltage are detected, errors can easily be predicted, which are associated with an increase or decrease in electrical power or impedance.
  • the fault may be a cable break or cable short. Especially with these two types of error early detection is possible on the basis of characteristic frequency patterns. Before a cable break or short circuits, sporadic sparking or isolated breakdowns may occur, which are associated in particular with charging processes or high-frequency discharge processes.
  • the fault may also relate to an electromagnetic radiation of a device of the transport machine into the electrical system of the transport machine.
  • EMC electromagnetic compatibility
  • a feature of the frequency spectrum in the range of a frequency greater than 1 megahertz can be used. These frequencies occur, for example, more intensely only in the run-up to a cable break or short circuit or as a result of faulty electromagnetic radiation. table irradiation.
  • the feature may be at a frequency less than 100 MHz (megahertz).
  • the detection values can be detected at a vehicle electrical system of the first transport machine.
  • the electrical system can contain at least two parts, between which a separating device is arranged, through which the two parts can be electrically separated from each other.
  • a warning may be issued and / or at least one of the disconnecting devices (46) may be actuated.
  • a decision is made as to which measures are to be initiated.
  • An embodiment also relates to a transport machine, comprising:
  • a vehicle electrical system containing at least two parts, a separating device arranged between the at least two parts, with which the two parts can be electrically separated from each other,
  • a first detection device on the vehicle electrical system preferably on a first part of the at least two parts
  • a control unit which is connected to the separating device or with a warning unit, and which controls the separating device or the warning unit depending on detection values detected by the detection device.
  • This transport machine is particularly suitable for methods for error prognosis, because at a predicted Turn off parts of the vehicle electrical system so that the predicted fault can not occur at all. Additionally or alternatively, an automatic warning message can be generated. For the rest, the technical effects mentioned above for the method apply. A targeted switching off of individual segments can also be used to localize the error or the signals indicating the error.
  • the two parts can be redundant to each other. At the two parts can preferably be connected to each other redundant units of the transport machine. Redundancy is increasingly being used for automatic driver assistance systems, in particular for assistance systems which engage in vehicle control for a longer period, e.g. for more than one second or more than 3 seconds. Examples of such systems are: steering assistant, brake assist, overtake assistant, etc., i. Control units with central control tasks, control units for a steering system, control units for braking the transport machine.
  • the redundancy can still be ensured despite the separation of a faulty segment.
  • the transport machine also contains a memory device for storing comparison features, comparison spectra, detection values acquired by the detection device / sensor, or spectra calculated from the detection values.
  • the signals detected by the detection unit can be transformed in one embodiment into the frequency domain.
  • a transmitting unit can then send the signals detected by the detecting unit or the transformed signals to a collecting unit, for example to a server which is also called a service providing computer.
  • a communication connection in particular a bus system, which lies between the control unit and the separation unit or the separation units.
  • the same data transmission system or another data transmission system can be used for the transmission of the detection values, in particular before the transformation into the frequency domain.
  • the further separation unit can switch on the occurrence of the predicted or predicted error or other serious errors and is eg a fuse or a circuit breaker.
  • an error is initially predicted. Subsequently, signal propagation time measurements are carried out in the vehicle electrical system in order to determine a segment of the electrical system in which the cause of the signals whose occurrence has caused the forecast of the fault. This segment can be separated from the rest of the vehicle electrical system as a precaution and / or it can be issued a warning message.
  • a warning message is particularly sufficient in cases where the expected error is less serious or in which the error is expected only after a certain time, for example, in a period that is greater than a week.
  • a protection concept for on-board systems is specified by means of pattern recognition in the frequency domain.
  • Fuses and circuit breakers are detected and repaired. In the event of a short circuit, the fuse will cause a higher current than permitted during normal operation. With fuses this leads to a thermal overload and thus to the separation of the nets. An automatic circuit breaker uses the additional energy to activate a switch and thus switch off the affected network.
  • Protective devices are usually accommodated in vehicles / transport machines in a central fuse box.
  • An undervoltage contactor is usually integrated in the individual components of the vehicle, so that after detection of an undervoltage in the device, the component turns off or via an implemented energy buffer, which is installed in the components, for example in the form of batteries or buffer capacitors, the other function can be maintained for a period of time.
  • An overvoltage contactor is usually provided by a diode or an overvoltage arrester, eg surge arrester or lightning discharge protection, which becomes conductive at a certain voltage.
  • the invention relates to, for example, vehicles / transport machines with electrical wiring systems, which detect errors in
  • On-board networks of vehicles, in particular short circuits, on the basis of frequency patterns allows.
  • the frequency patterns result from the detection of electrical characteristics, e.g. Current and voltage, and their mapping in the frequency domain.
  • the basis for detecting or detecting errors in on-board networks is that each component has a characteristic fingerprint in the frequency domain. Typical errors, such as Serial arcs occurring in the event of a cable break - precursor to a short circuit - also show a characteristic frequency response.
  • a suitable procedure for fault finding and troubleshooting in a vehicle electrical system is, for example, in the following procedure:
  • the method described is suitable for detecting errors which are particularly difficult to detect, such as e.g. Cable breaks, i. serial
  • Short circuits as well as typical parallel short circuits, e.g.
  • the chafing of cables causes one to predict ahead of time.
  • the aim is to prevent damage to other components of the electrical system or the entire system and the necessary replacement of components and lines, e.g. are subject to aging, that they can be consumed more efficiently.
  • the state of components in the electrical system can be monitored and recorded so that the quality of the electrical system and its components, in particular its availability, can be improved.
  • Interference coupling eg with regard to electromagnetic compatibility, can be measured and stored at runtime and analyzed at runtime or after operation and detected errors are mitigated or remedied by countermeasures.
  • FIG. 1 shows method steps for constructing a database with characteristic features, e.g. for forecasting errors
  • FIG. 2 shows the chronological sequence during the construction and use of the database
  • FIG. 3 shows a vehicle electrical system, e.g. of a passenger vehicle,
  • FIG. 4 shows an infrastructure for generating the database
  • FIG. 5 method steps in error monitoring
  • FIG. 6 shows a typical spectrum for components and / or
  • Figure 7 shows a typical spectrum upon the occurrence of an error, e.g. a short circuit
  • FIG. 8 shows a voltage curve and a current profile at a detection device on the electrical system
  • FIG. 9 shows the spectrum with error feature calculated from the voltage curve and the current profile.
  • FIG. 1 shows method steps for constructing a database with characteristic features, eg for forecasting errors. The method begins in a method step 1, hereinafter also referred to as a step for short.
  • detection data in the time domain are first detected in a large number of cars / vehicles and then transformed into the frequency domain, for example voltage data, current data, performance data, and the like.
  • the transformed data is then transmitted via a radio network or in another way, eg via a service or maintenance network by means of wired transmission, to one or more storage computers and stored there. Alternatively, only the data in the time domain can be transmitted and stored.
  • a transformation into the frequency domain then takes place at a central location or at several central locations.
  • only the data relevant for an error detection or error prognosis can be transformed, for example, only the data of a vehicle within a specific period before the occurrence of a fault in this vehicle.
  • an error occurs in one of the vehicles.
  • the data of this vehicle are read from the database, preferably the spectra stored for that vehicle, in particular the spectra in a certain time before the occurrence of the error, e.g. within one week or within one month recalculated from the date of the error.
  • the spectra transmitted by other vehicles may be used, e.g. to have comparative values for error-free spectra.
  • a step 6 characteristic features of the spectrum are sought, which allow time as far back as possible from the time of error still a safe detection of a deviation.
  • This examination can be done manually, computer assisted or automatically. In particular, statistical evaluations can be carried out.
  • searching for characteristic features it is preferable to examine a plurality of vehicles with the same error, so that, if necessary, further maintenance is required before the determined characteristic feature for forecasting errors can be released. It must therefore be ensured that the deviations found in the spectrum are actually related to the error that has occurred and that the change in the spectrum did not occur only in the one vehicle due to its individual production or its individual properties.
  • probabilities of occurrence of the error in the chosen change may also be used.
  • a characteristic feature has been determined, then this can be used for the error prognosis and the error detection in future cases, which will be explained in greater detail below with reference to FIG.
  • the search of characteristic features can be carried out with the aid of the service providing computer on which the database is stored. Alternatively, another computer or another data processing system can be used for the examination.
  • the method for determining the features is in one
  • Step 7 finished.
  • FIG. 2 shows the chronological sequence during the construction and use of the database.
  • the time t is plotted.
  • a record is always generated when the vehicle has been running for 10 minutes, but at most once a day.
  • the data are detected, for example, shortly after starting, for example within 30 seconds.
  • the acquisition of the data may also be tied to other conditions, such as driving at a certain speed or in a certain range of speed.
  • data is continuously recorded while the vehicle is running. Even at standstill of the vehicle detection is possible.
  • a data set DSla is generated for a first vehicle.
  • the structure of the data records DSla etc. will be explained in greater detail below with reference to FIG.
  • the first vehicle for example, does not drive for a few days, so that no data records are recorded.
  • a data set DSlb for the first vehicle is generated.
  • a data set DSlc is generated for the first vehicle.
  • a data set DS2a for a second vehicle is generated and stored centrally or in the vehicle.
  • the generation of further data sets is indicated by interruption of the time beam 8.
  • another record DSld for the first vehicle is generated and stored, e.g. more than two weeks after time t4.
  • an error occurs in the first vehicle, for example on the same day as the record DSld has been generated.
  • the step 6 for searching for characteristic features explained above with reference to FIG. 1 is then carried out.
  • the software for error detection is then updated on the basis of the feature found in the first vehicle and in the second vehicle, so that the feature found in the forecast of errors in the electrical system of these vehicles can be considered in the future.
  • further data sets DS2b or DSle are generated by the second vehicle or by the first vehicle and transmitted to the database, for example to find deviations in other errors that occur later.
  • FIG. 3 shows a vehicle electrical system 10, e.g. of a passenger vehicle 110, see FIG. 4.
  • the vehicle electrical system 10 contains:
  • Segments 12 to 26 each of which contains a plus lead and possibly a minus lead, and which are connected in a ring structure in the order named,
  • the accumulator 28 being connected to the segment 26 and the accumulator 30 to the segment 18,
  • Separators 32 to 46 e.g. mechanical, electromechanical or electronic switches, e.g. Power field effect transistors, in particular MOSFETs (Metal Oxide Semiconductor Field Effect Transistor), which are connected in this order between the segments 12 to 26,
  • MOSFETs Metal Oxide Semiconductor Field Effect Transistor
  • control and communication unit SE on the bus system 50a, 50b.
  • the segments 12 and 24 are mutually redundant and serve, for example, the power supply of control units with central tasks. These control units can in each case be designed redundantly, ie two control units on the segment 12 and two control units on the segment 24.
  • the segments 14 and 22 are also mutually redundant and serve the power supply of control units to assist the steering of the vehicle, see, for example, the Steuerieri 90 and 92 on the segment 22nd
  • the segments 16 and 38 are also mutually redundant and serve the power supply of control units, which serve, for example, the automatic braking of the vehicle.
  • the measurement data for the method explained with reference to FIG. 1 are detected, for example, only at the segment 12.
  • measurement data can be acquired at all segments 12 to 16, 20 to 24 and optionally also at segments 18 and 26.
  • the equipment of each segment 12 to 16, 20 to 24 with a detection unit is only necessary, for example, for detecting transit time differences in the localization of a segment in which a fault is being made.
  • Ring topology selected a more meshed topology. Even with on-board networks without redundancy, the invention is used.
  • FIG. 4 shows an infrastructure 100 for generating the database.
  • the infrastructure 100 includes cars or vehicles 110 to 114 which are equipped with transmission units, for example transmission unit 102 of the vehicle 110. Furthermore, the infrastructure 100 includes a server 116.
  • the server 116 is a service-providing computer (DER), for example the following ones Ingredients contains: a memory Mem, for example a RAM (Random Access Memory) and / or a ROM (Read Only Memory),
  • DER service-providing computer
  • processor MP e.g. a microprocessor or a microcontroller that executes instructions stored in memory Mem
  • a transmitting / receiving unit R / S (Receive / Send), the transmitting part being optional
  • Mem Mem stores a plurality of data sets for a plurality of vehicles, see the two data sets DSla and DS2a.
  • the data record DSla relates to the vehicle 110.
  • the data record DS2a concerns the vehicle 112.
  • an identification date e.g. ID1
  • - spectrum data e.g. Spl include the spectrum for the values detected within a given time window in the respective vehicle 110, 112 or 114.
  • a time date e.g. Tl
  • Tl indicates the day and / or time the record was created.
  • the data sets DSla, DSlb, etc., DS2a, Ds2b, etc., are transmitted from the vehicles 110 to 114 to the server 116, see data link 122, 124 and 126, respectively.
  • the data sets DSla etc. can also be electronically encrypted and / or electronically signed by the vehicles 110 to 114 are transmitted to the server 116.
  • data transmission from the server 116 to the vehicles is possible, for example, to confirm receipt the records, to update program components of the vehicles 110 to 114 or for other purposes.
  • FIG. 5 shows method steps in the error monitoring and / or the prediction of errors.
  • the method begins in a method step 200, hereinafter also referred to as a step for short.
  • a subsequent step 202 typical patterns or characteristics for the prognosis are determined, as explained above with reference to FIG.
  • This processor may be located in or outside the vehicle, e.g. in a service-providing computer of a workshop or service center.
  • detection values are recorded on the vehicle electrical system 10; in particular, the sampling of voltage U (t) and current I (t) is carried out at defined locations of the vehicle electrical system 10, for example at the segment 12 or 22.
  • a step 204 thereafter, the transformation of the information from U / l (impedance) by Fourier transformation in the frequency domain.
  • the power U * I can be transformed, only the voltage or only the current profile.
  • a signal processor which is contained in the control and communication unit SE is used for the transformation.
  • the transformation can also be performed outside the vehicle, e.g. in a service or maintenance center.
  • a step 206 the frequency range (amplitude response) calculated in step 204 is compared with typical patterns as deposited in step 201, and from this identification of errors or prognosis of errors in step 208. The identification or prognosis of Errors thus occur in the frequency domain. If it is determined in step 208 that there is no error, the method is continued, for example, in method step 202, for example without a break or at the next start of the vehicle, on the next day of travel or in the next month of driving. Thus, the method is in a loop from the method steps 202 to 208. This loop is only exited in step 208 if an error is found or predicted. However, steps 202 through 208 may be performed only during maintenance.
  • a step 210 follows, which relates to the initiation of countermeasures, for example switching off the affected segment of vehicle electrical system 10 and / or issuing warning messages to the driver of the vehicle.
  • the segment to be switched off can be determined, for example, via travel time measurements in which several of the sensors on the vehicle electrical system are included. Alternatively, it is tried sequentially or according to a search strategy which segment 12 to 26 is the defective segment or the segment for which an error is predicted. If the procedure is only performed during maintenance, the error can be rectified immediately.
  • the method is then completed in a step 212. Alternatively, the method can also be continued in step 202, see arrow 214, in order, for example, to forecast further errors.
  • FIG. 6 shows a typical spectrum 220 for components and / or consumers on the vehicle electrical system.
  • the frequency is plotted with negative and positive values.
  • the spectrum 220 has three maxima in its left part.
  • the right part of the spectrum 220 also has three maxima, of which, however, two maxima have larger amplitude values than the maxima on the left side.
  • FIG. 7 shows a typical spectrum 230 when an error occurs, eg a short circuit. Compared to the spectrum 220, the spectrum 230 has a similar course on the left side, ie three maxima.
  • the right side of the spectrum 230 has only two maxima, with the first maximum being in the range of the two first maxima of the spectrum 220 and the third maximum at high frequencies on the right side of the spectrum 230 being the corresponding maximum of the spectrum 220 at that frequency significantly surpasses and even represents the global maximum.
  • the global maximum was assigned to an error in study 6, see FIG. 1, which occurred later or had already occurred.
  • FIG. 8 shows a voltage curve 250 and a current curve 252 at a detection device on the vehicle electrical system 10, as it is determined, for example, in step 202, see FIG. 5, in the time domain. Initially, the voltage is at low levels, then increases and then drops again. The current starts at high values, then drops and again alternates several times.
  • FIG. 9 shows the spectrum 260 with error feature 262 calculated from the voltage curve 250, see FIG. 8, and the current profile 252, see also FIG. 8, in step 204, see FIG. 5. high amplitude at a high frequency, then an error is predicted or detected.
  • the spectrum 260 is slightly changed compared to the spectrum 230 of FIG. 7, which is due to vehicle-specific deviations.
  • Current and voltage can, for example, be multiplied only in the time domain, whereupon the spectrum is then calculated.
  • the spectrum is then calculated.
  • the spectrum of the voltage profile and the spectrum of the current profile are calculated. Thereafter, a convolution of the spectra in the frequency domain.
  • a calculation of the impedance spectrum is possible in two ways. Likewise, only the voltage spectrum or only the current spectrum can be leranalysis or to predict errors.
  • Suitable error characteristics of the frequency spectrum are, for example, suitable: the position and the amplitude value of a global minimum,
  • the signal energy i. the area under the curve in a certain frequency range is a typical characteristic that can be evaluated in the frequency domain and that is often much more meaningful than, for example, a minimum or maximum consideration.
  • the steepness of the curve or the waviness of the curve may be other criteria, in particular relative to a certain frequency range.
  • the transformation into the frequency domain may, for example, be a Fourier transformation, a Laplace transformation, a Z transformation or another transformation.
  • the electrical systems lead, for example, voltages less than 100 volts or even less than 60 volts, but greater than 5 volts or greater than 10 volts.
  • the methods described can also be used in the power grid.
  • the power grid may carry voltages greater than 100 volts or greater than 400 volts.
  • the voltages in the drive network can typically be less than 1000 volts. Due to the use of batteries or rechargeable batteries, mainly DC mains are used.
  • the voltage on DC on - board networks is comparatively constant and fluctuates, for example, by less than plus / minus 10 percent of a mean value or nominal value.
  • the methods are not limited to DC networks and can thus also be used in AC networks.

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  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Testing Of Short-Circuits, Discontinuities, Leakage, Or Incorrect Line Connections (AREA)

Abstract

L'invention concerne un procédé permettant le pronostic d'une erreur dans une machine de transport. Ledit procédé consiste à : détecter (2) au moins un type de valeurs de détection dans la plage temporelle dans une première machine de transport ; enregistrer (2) les valeurs de détection ou enregistrer les spectres de fréquences des valeurs de détection ; attendre une erreur détectable, de préférence sans les valeurs de détection enregistrées ou les spectres de fréquences enregistrés ; examiner (6) si les spectres de fréquences enregistrés avant l'apparition de l'erreur ou les spectres de fréquences calculés à partir des valeurs de détection enregistrées avant l'apparition de l'erreur ne comportent pas au moins un signe distinctif qui indique prématurément l'apparition de l'erreur ; employer le signe distinctif pour la détection prématurée de l'erreur ou pour la détection de l'erreur dans la première machine de transport ou dans une deuxième machine de transport.
EP13713819.4A 2012-04-25 2013-03-25 Procédé pour le pronostic d'une erreur ou pour la détection d'une erreur dans une machine de transport ainsi que machine de transport Withdrawn EP2810255A1 (fr)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
DE102012206836A DE102012206836A1 (de) 2012-04-25 2012-04-25 Verfahren zur Prognose eines Fehlers oder zur Fehlererfassung in einer Transportmaschine sowie Transportmaschine
PCT/EP2013/056182 WO2013160039A1 (fr) 2012-04-25 2013-03-25 Procédé pour le pronostic d'une erreur ou pour la détection d'une erreur dans une machine de transport ainsi que machine de transport

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EP2810255A1 true EP2810255A1 (fr) 2014-12-10

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EP13713819.4A Withdrawn EP2810255A1 (fr) 2012-04-25 2013-03-25 Procédé pour le pronostic d'une erreur ou pour la détection d'une erreur dans une machine de transport ainsi que machine de transport

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EP (1) EP2810255A1 (fr)
DE (1) DE102012206836A1 (fr)
WO (1) WO2013160039A1 (fr)

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DE102020108861A1 (de) 2020-03-31 2021-09-30 Audi Aktiengesellschaft Verfahren zum Ermitteln eines Zustands eines Bauteils
CN112319550B (zh) * 2020-10-30 2022-11-25 中车青岛四方机车车辆股份有限公司 一种基于列车初上电的故障诊断方法、系统、装置及列车
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