• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a system for processing a track (2) with a track construction machine (1) which comprises a machine control (4) and a working unit (3) controlled by it, sensors (6) being arranged to monitor the working unit (3). The sensors (6) are coupled to a data acquisition module (7) for the separate acquisition of sensor data (SD), the data acquisition module (7) being connected to a computer unit (8) in which a first algorithm (P1) for calculating result data (ED) is set up from the sensor data (SD). In this way, the system includes additional structural components for processing sensor signals (SS). With the data acquisition module (7) and the computer unit (8), different evaluations of the work operation can be carried out independently of an existing monitoring function.
    公开号:AT17191U1
    申请号:TGM50107/2020U
    申请日:2020-05-20
    公开日:2021-08-15
    发明作者:
    申请人:Plasser & Theurer Export Von Bahnbaumaschinen Gmbh;
    IPC主号:
    专利说明:

    description
    SYSTEM FOR MACHINING A TRACK
    TECHNICAL AREA
    The invention relates to a system for processing a track with a track construction machine, which comprises a machine control and a working unit controlled therewith, sensors for monitoring working variables being arranged. The invention also relates to a method for operating the system.
    STATE OF THE ART
    A generic system is known from AT 520 698 A1. The system is used to monitor the load on a tamping unit while a track is being worked on. For this purpose, sensors are arranged that record measurement data over a period of time and forward it to an evaluation device. A load-time curve for cyclical work processes of the tamping unit is derived from the measurement data. Conclusions gained from this about the load situation of the tamping unit are used to specify maintenance measures or maintenance intervals.
    DISCLOSURE OF THE INVENTION
    The invention is based on the object of expanding the use of the sensors present in a system of the type mentioned at the beginning. Furthermore, a correspondingly improved method for operating the system is to be specified.
    According to the invention, these objects are achieved by the features of the independent claims 1 and 11. Dependent claims indicate advantageous embodiments of the invention.
    It is provided that the sensors are coupled to a data acquisition module for the separate acquisition of sensor data and that the data acquisition module is connected to a computer unit in which a first algorithm for calculating result data from the sensor data is set up. In this way, the system includes additional structural components for processing sensor signals. With the data acquisition module and the computer unit in which the application-specific algorithm is set up, different evaluations of the work operation can be carried out independently of an existing monitoring function. Concrete advantages result from a flexible configuration of the sensor data acquisition and from the possibility of adapting the result data calculation.
    In a further development, the computer unit is set up to calculate at least one parameter from the sensor data recorded during a work process, the computer unit in particular being coupled to the machine control for the automated specification of optimized work parameters. A continuous improvement of the work processes carried out with the working unit is thus achieved. The calculated parameter is matched to the working unit in use and characterizes the quality of the corresponding work process. The result of this improvement is a higher-level control loop at the level of a control system.
    The data acquisition module is advantageously set up for multi-channel data acquisition and coupled as a slave to the computer unit designed as a master. This system architecture enables an efficient connection of several sensors to the subsystem consisting of the data acquisition module and computer unit.
    In a further improvement, a monitoring device is arranged for monitoring the working unit, which monitors the sensor data at a lower sampling rate (e.g. 1 Hz) than the data acquisition module (e.g. sampling rate in the kHz range). So that is for the
    Monitoring a simple but sufficient data processing possible. For the additional sensor evaluation by means of a computer unit, however, a database with a high temporal resolution is available.
    An advantageous expansion of the system provides that the computer unit is coupled to a database via communication means in order to receive program data for changing the first algorithm or for setting up a second algorithm. The evaluations carried out by means of the computer unit can thus be modified in a simple manner. With the system, new analyzes of the work process can be carried out without having to make structural changes. In addition, new evaluation algorithms can be tested with the system before adjustments to the work process are derived.
    It is advantageous if the communication means comprise a VPN router. All devices connected to this VPN router can thus use a secure VPN tunnel. This affects the computer unit and other system components that exchange data with the database. The system-integrated VPN router expands the possibilities for secure transmission of various data.
    In a further improvement, the computer unit is connected to a memory device in order to store sensor data and / or result data. The memory device is expediently dimensioned in such a way that all result data and possibly also all sensor data are stored up to the end of a predetermined readout interval. For example, the readout interval corresponds to a maintenance interval of the monitored working unit. In addition, data stored on the storage device can be called up at any time by means of remote access, preferably via a VPN tunnel. In particular, it makes sense to transfer the result data via remote access. The large data volume of the sensor data, on the other hand, is saved in the storage device and read out when the system is revised.
    So that result data and possibly sensor data are available centrally, it is advantageous if the computer unit is coupled to a computer network (cloud) for data transmission via a modem. In this way, the data can be accessed at any time via an online application (web app).
    Advantageous forms of the system include a tamping unit and / or a stabilizing unit as the working unit. Vibrating tools comprising such work units, which introduce vibrations into a machined gravel track. With sensors arranged on the work units, conclusions can be drawn about the quality of a track ballast bedding and a compaction of the track ballast. Thus, the system not only provides information about the condition and operation of the working unit itself, but also about the condition and processing of the track.
    Advantageously, a motion sensor for detecting a vibration cycle is arranged as the sensor. Both with the tamping unit and with the stabilization unit, the movement and force curves can be used during an oscillation cycle in order to obtain parameters for a compaction process.
    In the method according to the invention for operating the system, sensor signals for monitoring the working unit are generated by means of the sensors, the sensor signals being fed to the data acquisition module for separate sensor data acquisition, and result data being calculated from the sensor data using the first algorithm set up in the computer unit. With this process sequence, result data are derived from the sensor data in parallel with the monitoring of the working unit. The focus is not initially on the characteristics or the quality of the result data, but on the use of a freely definable algorithm using the system components specially provided for this purpose. These are the data acquisition device and the computer unit.
    An advantageous further development of this method provides that characteristic values of a work process are calculated as result data and transmitted to the machine control. With this sensible use of the system, a control loop enables the automated improvement
    of the work processes that are carried out by means of the working unit.
    The method is improved by adapting the algorithm that is easy to carry out, with program data for changing the first algorithm or for setting up a second algorithm being transmitted to the computer unit. This is done either via a connection via a VPN tunnel or via a direct connection to a computer on which the program data is provided.
    It is advantageous if new program data are loaded into a memory of the computer unit in a first step and if the new program data are activated in a second step after restarting the computer unit. This two-step update process ensures that any faulty program data does not result in a system failure. Since a new program is only activated after a restart, the computer unit (processor) is always in a defined state.
    It makes sense to transfer result data from the computer unit to an external computer via a VPN tunnel or via an offline connection. The data is thus available centrally or decentrally for further processing and can be further used and archived in a variety of ways.
    BRIEF DESCRIPTION OF THE DRAWINGS
    The invention is explained below in an exemplary manner with reference to the accompanying figures. It shows in a schematic representation:
    Fig. 1 track construction machine
    Figure 2 is a block diagram of the system
    Fig. 3 Processing of program data
    4 processing of sensor and result data
    DESCRIPTION OF THE EMBODIMENTS
    The system comprises, for example, a tamping machine as a track construction machine 1 for processing a track 2. Such a track construction machine 1 has, as working units 3, a tamping unit and a lifting and straightening unit. In addition, a stabilizing unit can be arranged as the working unit 3. The working units 3 are controlled by means of a machine control 4. Furthermore, the track construction machine 1 comprises a measuring system 5 for recording an actual position of the track 2.
    To monitor the working unit 3 designed as a tamping unit, sensors 6 are arranged. An exemplary sensor 6 is described in the Austrian patent application AT 521 765 A1 by the same applicant. Sensors 6 attached to the tamping unit or to the other working units 3 measure accelerations and / or forces that act on individual unit components. Temperature measurements can also be useful in order to monitor the state of a unit 3.
    The respective sensor 6 generates sensor signals Ss, which are recorded by means of a data acquisition module 7 (data acquisition module, DAQ) and processed further as sensor data Sp. For this purpose, the data acquisition module 7 is connected to a computer unit 8. A first algorithm P + (program) is set up in this computer unit 8 in order to calculate result data Ep from the sensor data Sp. These result data Ep serve to evaluate the work processes carried out with the working units 3 or to evaluate the condition of the track 2 being worked. For this purpose, the result data Eo include corresponding characteristic values.
    The computer unit 8 and the data acquisition module 7 are advantageously interconnected in a master-slave architecture. The data acquisition module 7 comprises, for example, several DAQ units with 12 to 16 channels, a sensor signal Ss being supplied to each channel. The data acquisition module 7 acquires the sensor signals Ss with a high scanning
    rate in the range of a few kilohertz in order to generate sensor data Sp with a high temporal resolution for the subsequent processing.
    For a pure monitoring function, however, sensor data Sp with a lower resolution are sufficient. Usually only a few sensor data Sp per unit of time (e.g. sampling rate 1 Hz) are required in order to follow the course of wear of an aggregate component and to estimate any maintenance measures. It is therefore sensible to set up separate data processing with its own data acquisition unit 9 for the monitoring function. A monitoring device 10 includes further components, for example a microprocessor 11 and a modem 12 for transmitting monitoring data Up to a computer network (cloud) 13. Such a monitoring device 10 is described in AT 520 698 A1 by the same applicant.
    A modem 12 of the monitoring device 10 or a separate modem is expediently also used for a transmission of the result data Ep generated by the computer unit 8. In this way, the result data Eo and possibly also transmitted sensor data Sp are available centrally in the computer network 13. For example, the data Sp, Ep can be displayed and further processed (web access) by means of a secure online application (web app) on a computer 14 with a network connection.
    The track-laying machine 1 comprises, for example, a high-performance Linux server as the computer unit 8. This makes it possible to process the signal data Sp acquired at a high sampling rate in real time. In any case, it makes sense to coordinate the sampling rate of the data acquisition module 7 and the computing power of the computer unit 8 in order to ensure real-time calculation of result data Ep. Various characteristic parameters of the work process can thus be determined directly on the track construction machine 1.
    In addition, it is advantageous if the computer unit 8 is designed in such a way that CPU capacities are also available for processing advanced mathematical algorithms. These mathematical algorithms are models and calculation algorithms for assessing the condition of machine parts and for adapting work parameters. All algorithms set up in the computer unit 8 are executed as tasks T +;, T2, Tn (processes). Specifically, a master application M runs on the computer unit 8, which starts and initiates individual tasks T +; T2, TA in a coordinated manner (FIG. 3).
    In addition or as an alternative to the transmission of sensor and result data Sp, E »to the computer network 13, these data So, Ep are stored in a storage device 15 which is connected to the computer unit 8. For example, a separate processor (server) is implemented in the computer unit 8, which combines various system variables and stores the desired data Sp, Ep on a mass storage device of the storage device 15. The stored data Sp, Eo can be transmitted to a computer 14 via a data interface 16, for example during an overhaul of the track-laying machine 1.
    In the embodiment variant shown in FIG. 2, the system comprises communication means 17 for comparing program data with a database 18. For example, a VPN router which is connected to the computer unit 8 is provided for this purpose. In this way, sensor and result data Sp, Ep can also be transmitted via a VPN tunnel 19.
    The VPN tunnel 19 is advantageously also used for software updates of the computer unit 8 (FIG. 3). To this end, an initiated task T. checks whether a new algorithm is available in the database 18. For example, a comparison with the current versions of the running tasks T +, T2 takes place for this purpose. If necessary, a changed algorithm P + or a new algorithm P2 is loaded via the VPN tunnel 19, compiled and added to the task list T. The new tasks are started and processed by restarting the computer unit 8.
    Such an update can also be used to analyze processes on the track-laying machine 1 that have not been taken into account so far. First, a new algorithm P> »adapted to the problem to be analyzed is loaded into the computer unit 8 and compiled. At-
    For example, a corresponding task writes the sensor data Sp of some selected sensors 6 in the memory 15 when a predetermined event occurs. After a sufficient recording time, the collected data So, Eo are uploaded to the computer network 13 and analyzed.
    A further development of the system is shown in FIG. The working unit 3 is monitored by means of various sensors 6. Via the data acquisition module 7, these sensors 6 and other sensors 6 (inertial measuring unit, laser cutting sensor, hydraulic pressure meter, etc.) arranged on the track construction machine 1 supply the computer unit 8 with sensor data Sp. By means of various algorithms P- +, P2, Pn, control-relevant parameters are calculated as result data Ep . The respective characteristic values are fed back into the machine control 4, which subsequently results in an active intervention in the work process.
    For this purpose, the machine control 4 (control system of the track construction machine 1) comprises a central control 20, by means of which several decentralized subsystems 21 are coordinated. These are, for example, a subsystem 21 for adjusting the speed of an eccentric drive to generate vibrations, a subsystem 21 for a pick opening width of a tamping unit, a subsystem 21 for an automatic immersion system for tamping tines and a subsystem 21 for unit positioning.
    Thus, physical quantities of the affected work process are recorded and measured. The recorded variables are fed to the computer unit 8 as a data stream, with all tasks T +, T2, T- having full access to this sensor data Sp. When tasks T4, T2, Tn are executed, characteristic parameters of the work process are determined. These parameters are then fed back to the central controller 20 in order to predefine the subsystems 21 optimized working parameters. In this way, a higher-level control loop with an observation-based controller is set up at the level of a control system.
    In an advantageous further development, the calculation of the optimized working parameters takes place directly in the computer unit 8. For this purpose, corresponding algorithms P +, P », P} are set up in the computer unit 8. The newly calculated working parameters are given to the central controller 20. No parameter calculation therefore takes place in the machine control 4 itself. Safety requirements applicable to the machine control 4 are not impaired in this way.
    The specification of new working parameters is explained in more detail using the example of multiple tamping by means of a tamping unit. In the case of multiple tamping, vibrating tamping tines are lowered into a ballast bed several times at the same point and provided in order to improve the ballast compaction.
    For parameter optimization, sensor data SD is initially acquired over a longer observation period. For example, the pressures and strokes of the auxiliary cylinders of the tamping unit are recorded. For each recorded stuffing cycle, characteristic parameters are calculated, which serve as basic data in a next step.
    The basic data acquired with the present system are available offline in order to train a prediction model. Specifically, the recorded data and a respective target variable (number of stuffing processes per stuffing cycle) serve as training data. The trained prediction model corresponds to a new algorithm P », which enables the target variable to be predicted.
    By testing and validating the new algorithm P; to be further improved. The test data used differ from the previously used training data. The predictions of the target variables are matched with predetermined target values in order to assess the quality of the predictive model. If necessary, the algorithm P >> is subjected to a new training step in order to improve the prediction quality.
    With the finished algorithm P », the specification of the respective working parameter takes place
    (Target variable) in real time directly on the track construction machine 1. As soon as the tamping ax penetrates the ballast bed, the sensors 6 deliver meaningful sensor data Sp for calculating parameters for the condition of the ballast bed. In any case, when a first stuffing process has ended, there is sufficient sensor data Sp to calculate reliable result data Ep. In the present example, the result data Eo »of the machine control 4 specify in real time whether a further tamping process is necessary at the same point in order to achieve a desired compaction.
    Another advantage of the present system results in multi-sleeper tamping units with several tamping units arranged one behind the other. These tamping units are lowered together into a ballast bed in order to tamp several sleepers at the same time. Here, the sensor data SD recorded and processed in real time are used to control the individual tamping units differently. Specifically, the condition of the ballast bed determined when the tamping ax is immersed is used to specify different auxiliary pressures. If necessary, the individual tamping units are also given different delivery times. In the case of simultaneous under-tamping across several sleepers, there is sometimes the problem that the ballast bed in the initial state has a different ballast compaction under each sleeper.
    For each tamping unit, a characteristic value calculated from the assigned sensor data SD indicates the respective degree of compaction at the relevant point on the ballast bed already during an immersion process. By means of a corresponding algorithm P2, the respective subcontrol is given an adapted supply pressure and, if necessary, an adapted supply duration. At places with an already increased degree of compaction, less tamping energy is introduced into the ballast bed by reducing the setting pressure and the setting time. At immersion points with a low degree of compression, however, there is a provision with increased pressure and longer duration. In this way, a homogeneous compaction of the ballast is achieved over the bedding section processed with the multiple tamping unit.
    权利要求:
    Claims (15)
    [1]
    1. System for processing a track (2) with a track construction machine (1) which comprises a machine control (4) and a working unit (3) controlled therewith, sensors (6) being arranged to monitor the working unit (3), characterized that the sensors (6) are coupled to a data acquisition module (7) for the separate acquisition of sensor data (Sp) and that the data acquisition module (7) is connected to a computer unit (8) in which a first algorithm (P +) for calculating Result data (Ep) from the sensor data (Sp) is set up.
    [2]
    2. System according to claim 1, characterized in that the computer unit (8) is set up to calculate at least one parameter from the sensor data (6) recorded during a work process and that in particular the computer unit (8) with the machine control (4) for automated specification optimized working parameters is coupled.
    [3]
    3. System according to claim 1 or 2, characterized in that the data acquisition module (7) is set up for multi-channel data acquisition and is coupled as a slave to the computing unit (8) designed as a master.
    [4]
    4. System according to one of claims 1 to 3, characterized in that a monitoring device (10) is arranged for monitoring the working unit (3) which records the sensor data (Sp) at a lower sampling rate than the data acquisition module (7).
    [5]
    5. System according to one of claims 1 to 4, characterized in that the computer unit (8) is coupled via communication means (17) to a database (18) to receive program data for changing the first algorithm (P +) or for setting up a second algorithm (P2) to receive.
    [6]
    6. System according to claim 4, characterized in that the communication means (17) comprise a VPN router.
    [7]
    7. System according to one of claims 1 to 5, characterized in that the computer unit (8) is connected to a memory device (15) in order to store sensor data (Sp) and / or result data (Ep).
    [8]
    8. System according to one of claims 1 to 6, characterized in that the computer unit (8) is coupled to a computer network (13) for data transmission via a modem (12).
    [9]
    9. System according to one of claims 1 to 7, characterized in that it comprises a tamping unit and / or a stabilizing unit as the working unit (3).
    [10]
    10. System according to claim 8, characterized in that a motion sensor for detecting an oscillation cycle is arranged as the sensor (6).
    [11]
    11. The method for operating a system according to one of claims 1 to 10, wherein by means of the sensors (6) sensor signals (Ss) for monitoring the working unit (3) are generated, characterized in that the sensor signals (Ss) for separate sensor data acquisition the data acquisition module (7) and that result data (Ep) are calculated from the sensor data (Sp) by means of the first algorithm (P +) set up in the computer unit (8).
    [12]
    12. The method according to claim 11, characterized in that characteristic values of a work process are calculated as result data (E>) and transmitted to the machine control (4).
    [13]
    13. The method according to claim 11 or 12, characterized in that program data for changing the first algorithm (P +) or for setting up a second algorithm (P>) are transmitted to the computer unit (8).
    [14]
    14. The method according to claim 13, characterized in that in a first step new program data are loaded into a memory of the computer unit (8) and that in a second step after a restart of the computer unit (8) the new program data are activated.
    [15]
    15. The method according to any one of claims 11 to 14, characterized in that result data (Ep>) are transmitted from the computer unit (8) to an external computer (14) via a VPN tunnel or via an offline connection.
    For this purpose 2 sheets of drawings
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    WO2018219570A1|2017-05-29|2018-12-06|Plasser & Theurer Export Von Bahnbaumaschinen Gmbh|Method and device for compressing a track ballast bed|
    CN110273334A|2018-03-16|2019-09-24|中国铁建高新装备股份有限公司|A kind of screen scarifier intelligence control system and its control method|
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    WO2020057865A1|2018-09-18|2020-03-26|Plasser & Theurer Export Von Bahnbaumaschinen Gmbh|Tamping unit and method for tamping sleepers of a track|
    DE202008010351U1|2008-08-04|2008-12-11|Db Netz Ag|Device for bearing diagnosis on eccentric shafts of tamping machines by means of vibration sensors|
    AT520698B1|2017-12-07|2020-09-15|Plasser & Theurer Export Von Bahnbaumaschinen Gmbh|Method and system for load monitoring of a tamping unit|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    EP20167556|2020-04-01|
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