EP1163789A1 - System and method for especially graphically monitoring and/or remote controlling stationary and/or mobile devices - Google Patents

Abstract

The invention relates to a system and a method for especially graphically monitoring and/or remote controlling stationary and/or mobile devices (F1..Fn), especially vehicles, semitrailers for lorries, building machines, farm vehicles, swop platform bodies and/or containers, from a centre (15) by means of a signalling device (MC). The mobile device (MC) is provided with a first function block (BB) for detecting measuring values, monitoring and/or giving an alarm according to rules which can be given and a second function block (BC) for storing application-specific data of the mobile device (MC). The centre (15) and the mobile device (MC) are provided with means for communicating via at least two communications channels (B1, B2). The first communications channel (B1) is provided for communicating between a communications server (KS) of the centre (15) and the second function block (BB) of the mobile device (MC) and the second communications channel (B2) is provided for communcating between a visualising system (VS) of the centre (15) and the second function block (BB) of the mobile device (MC).

Description

description

System and method for in particular graphic monitoring and / or remote control of stationary and / or mobile devices

The invention relates to a system and a method for, in particular, graphic monitoring and / or remote control of stationary and / or mobile devices, in particular vehicles, construction machines and / or containers, by means of a signaling device from a central office.

The invention further relates to a signaling device, a visualization, operating and / or observation system, a computer-readable medium and a program module for such a system.

Such a device is used in particular in vehicles, for example passenger cars, commercial vehicles, construction machines, agricultural machines, etc. It is often desirable to systematically record operating data and monitor the vehicles.

Such a device is known from GB 2,194,119 AI. The data acquisition device contains input sensors that record the status or certain security conditions. In addition, a signal processing device is provided that creates a status report that contains the identity and location of the data acquisition device and the respective operating data. A dialer and a radio telephone are connected to the data acquisition device and transmit the status report to a remote station.

The object of the invention is to ensure simple and secure communication between the signaling device and the control center. This object is achieved by a system for, in particular, graphic monitoring and / or remote control of stationary and / or mobile devices, in particular vehicles, construction machinery and / or containers, by means of a signaling device from a control center, the mobile device comprising a first function block for recording measured values , for monitoring and / or for issuing alarms according to predefinable rules and a second function block for storing application-specific data of the mobile device and wherein the center and the mobile device have means for communication via at least two communication channels, the first communication channel for communication between a communication server of the center and the second function block of the mobile device and the second communication channel for communication between a visualization system of the center and the second function block of the mobile device are provided.

This object is further achieved by a method, a visualization, operating and / or observation system, a computer-readable medium and a program module with the features specified in claims 16, 17, 18, 19 and 20.

The first function block for recording measured values, for monitoring and / or for issuing alarms, and the second function block for storing application-specific data of the mobile device form two logically separate function blocks which can be combined with one another as required. Thus, the first function block takes on all the automatic tasks relating to the monitoring and control of signals supplied, for example, by sensors or to be output via actuators. In particular, it also includes an aar system, measured value acquisition, measured value preprocessing and measured value storage. The second function block contains in particular the corresponding diagnostics as well as the application-specific programs, parameters and data records etc. Communication with the control center can be handled via at least two communication channels. The first communication channel is used for communication between the alarm system of the first function block and / or the alarm system of the control center, the communication server being coupled to the visualization system of the control center. The second communication channel is used by the visualization system in order to read out measurement data etc. from the mobile device without being influenced or blocked by the first channel. The overall result is a modular structure of the mobile device, which enables an open and expandable standard solution for monitoring, diagnostic, transport and logistics or fleet and fleet management tasks in one system and a single mobile device. The system consists of one or more mobile devices, a mobile device being arranged in each vehicle, which can communicate with one or more control centers or other corresponding authorized persons. Due to its modularity, the mobile device can be used for individual tasks as well as for a combination of these tasks. As a result, the mobile device and the control center, ie the entire system, can be used universally and in large numbers on the market. The integration of the signal / measured value acquisition and processing in a mobile device as an on-board computer results in an additional economic benefit for the customer, which enables integrated error detection of vehicles and / or load monitoring and thus minimizes service / workshop trips .

Online monitoring similar to a measuring device or an oscilloscope as well as offline evaluation of fault, error and / or alarm messages can be ensured in a simple manner by the mobile device having at least one transceiver, in particular a radio

Transceiver for temporary connection with min contains at least one center and / or with a subscriber authorized to receive messages.

A function which is particularly useful in connection with fleet management is achieved in that the mobile device has a third function block which comprises functions for location and / or fleet management and which has means for communication with a user at the location of the mobile device.

A short-term and / or a long-term data acquisition with a multitude of evaluation options, for example for service recommendations etc., can be ensured in an advantageous manner in that the mobile device has a data analyzer, which is integrated in particular in the first function block and which can be used to record specifiable data Measurement sequences by scanning input signals supplied by the data analyzer via signal sources is provided, that the mobile device is provided for stamping the recorded data signals with a date and time stamp, and that the mobile device for transmitting the scanned data sets to the central for graphic display within an operating and observation system is provided.

A reliable triggering of alarm messages can be achieved in that the mobile device has an alarm system which is integrated in particular in the first function block and which is provided for the transmission of alarm messages according to predefinable rules and for securing the transmitted messages.

A logable and thus traceable handling of the alarm messages is further improved in that the alarm system for storing alarm messages in the mobile device, for sending the alarm message to a predefinable one Central and for monitoring an acknowledgment of the sent alarm messages by the central is provided.

A cost-saving possibility for changing parameters of the signaling device, for example in the event of an update of the operating software, can take place without separate personnel expenditure in that the application-specific data and programs that can be stored in the second function block can be loaded remotely from a control center.

A secure alarm output to a control center or to an authorized person can be further optimized in that the control center and the mobile device have means for communication via a third communication channel, the third communication channel in particular for communication between the communication server of the control center and the third block of the mobile device is provided.

A secure and unambiguous assignment of the messages, even with a large fleet of reporting devices, is ensured in that the mobile reporting device is assigned an identifier for identifying the mobile device, that the mobile reporting device has means for transmitting the identifier to the control center together with a message and that Has central means for storing and visualizing the identifier.

A user-friendly handling of the messages within the control center takes place in that the visualization system and / or the operating and monitoring system has an alarm window for the visual visualization of messages, in particular alarm, warning and / or fault messages, that the alarm window contains information for identifying the Message, in particular the identifier, date, time and an error description. The user-friendliness of the system is further optimized in that the visualization system and / or the operating and monitoring system of the central unit has means for an implicit selection of a mobile device assigned to a message in such a way that by selecting a message from a message table, in particular by double-clicking or by activating an input function, the mobile device assigned to the selected message is automatically selected for establishing a connection.

A further possibility for user-friendly handling of the system is that the visualization system and / or the operating and observation system of the control center has a telephone book window for the visualization of the mobile reporting devices managed by a control center.

For the telephone book, too, optimal handling in terms of user-friendliness can be achieved in such a way that the visualization system and / or the operating and monitoring system of the central unit has means for an explicit selection of a mobile device in such a way that by selecting a mobile device the selected mobile device for establishing a connection is selected automatically in the telephone book table, in particular by double-clicking or by actuating an input function.

Secure archiving of measurement results, etc. can be achieved inexpensively without costly personal use in that the central unit has means for automatically storing the data transmitted from the mobile reporting device to the central unit for archiving the data.

The devices, such as construction machinery, fleet vehicles, etc., coupled to the signaling device can be located on a can be achieved in such a way that the reporting device has a GPS module for locating a mobile device coupled to the reporting device, the reporting device being provided for transmitting the location data to the control center and the reporting device providing the GPS data date and time for the highly accurate date and time stamp used for data recording.

The invention is described and explained in more detail below on the basis of the exemplary embodiments illustrated in the figures.

Show it:

1 shows a block diagram of an exemplary embodiment for the basic structure of a system for monitoring and / or remote control of vehicles,

2 shows a schematic representation of the basic structure of the architecture and overall configuration of an alarm system and

3 shows a schematic illustration for graphic alarm processing by means of a visualization, operating and / or observation system.

1 shows a block diagram of an exemplary embodiment of an overall system for mobile data acquisition. The data acquisition system comprises vehicles FL.Fn of a vehicle fleet. The vehicles FL.Fn are each equipped with a data acquisition device MC, the data acquisition device MC and the interaction with other components of the respective vehicle FL.Fn being shown only on the basis of the vehicle Fl. The data acquisition device MC has input interfaces S1..S4, via which input signals are respectively supplied from data sources Ql..Q4. The first interface S1 is for processing, for example of input signals of a communication bus, as used in vehicles as a so-called CAN bus (GAN = Controller Area Network). Operating data for engine temperature, water temperature, oil pressure, oil temperature, battery voltage etc. are transmitted via such a data bus, for example. The second interface S2 is, for example, a serial interface, for example for connecting a keyboard, display etc. trained, while the third interface S3, for example as a so-called "On Board I / O" interface, for example for connecting

Sensors, sensors, etc. is provided. The fourth interface S4 is used for the optional connection of a GPS module (GPS = Global Positioning System). The data acquisition device MC has an output interface SA which forms the output, for example, of a GSM module (GSM = Global System for Mobile Communication), where the output interface is connected to a transmitting / receiving antenna 6. The vehicle F1 can establish a bidirectional data connection between the antenna 6 of the data acquisition device MC and an antenna 11 of a base station 10a. 10n via a radio interface 9. The base stations 10a. 10n of a GSM mobile radio network N are connected to a network operator 13 of the mobile radio network N. There is a connection 14 from the operator 13 of the mobile radio network N to a control center 15. Alternatively or additionally, a further data connection 16 between a receiver E and the operator 13 is possible via a further base station 17 as a mobile data connection 16. A computer 20 with data processing device 22, monitor 21 and keyboard 23 is used, for example, as a human-machine interface for communication between central unit 15 and data acquisition device MC.

1 shows the embedding of an alarm device MC within a system for monitoring and diagnosing vehicles FL.Fn, the arrangement being explained in more detail using the example of the alarm device MC contained in vehicle F1. Instead of the vehicles FL.Fn shown in FIG other mobile and stationary devices such as vehicles, machines, for example construction vehicles, cranes, containers, rail vehicles, etc. can also be integrated within such a system. The signaling device MC has input interfaces S1..S4, via which input signals originating from data sources Q1..Q4 can be fed. Such input signals can be, for example, signals that relate to the operational safety of the vehicle FL.Fn, such as water temperature, oil temperature, cooling temperature of a refrigerated vehicle, etc. In the reporting device MC, certain input signals are recorded according to the rules stored in the data acquisition device MC according to stored rules at specific times. The signals recorded in this way can then be transmitted to the center 15 and / or the receiver E via the output interface either at the request of the control center 15 or at the request of another receiver E. In this way, an effective fault diagnosis can be carried out, for example, in the event of a fault in the vehicle FL.Fn. In addition, there is the possibility of also recording certain input signals la..4a in the data acquisition device MC over a short period of time, for example by trigger events, for example automatically derived from the signals in the MC or started or stopped by operation from the control center, and thus highly current Receive machine and vehicle conditions based on a very up-to-date display and initiate appropriate maintenance or repair measures, etc. The recording of signals over a short period of time can also take place, for example, in the form of a direct dialog connection between the control center 15 and the data acquisition device MC via an online connection in the form of the air interface 9. The rules in the data acquisition device MC can be designed in such a way that an automatic alarm message can also occur when certain disturbance events occur, for example limit value violations. On the basis of the location data supplied via the GPS antenna 4, the data acquisition device MC can also transmit location data to the control center and perform a highly accurate date and time stamp when recording signals in the MC. On the one hand, this results in theft monitoring and, on the other hand, a clear fleet management of the vehicles of a vehicle fleet FL.Fn to be recorded from the control center 15 can take place. In addition, a voice connection between the driver of the vehicle F1 and the central unit 15 is also possible via the radio link 9 between the central unit 15 and the vehicle F1, without a separate radio transceiver being required for this. In the event of a fault, for example, a notebook etc. be connected and the recorded signals can be evaluated on site for error detection. An optimal representation of the information transmitted from the data acquisition device MC to the control center 15 is made possible by the fact that a software package is installed in the computer device 22, which software package is, for example, on the operating and monitoring system from Siemens WinCC or an OPC (OLE for Process Control ) based system or based on operating systems like Windows.

This also optimizes administration, for example of incoming alarm messages. In addition, special information for the FL.Fn vehicles, for example traffic radio, route guidance, data and / or order data, etc., can be transmitted from the head office in a vehicle-specific or fleet-specific manner. The rules in the data acquisition device MC for the acquisition and transmission of input signal data to the control center are stored in the data acquisition device MC in such a way that the rules can be downloaded from the control center 15 to the data acquisition device MC via the air interface 9.

2 shows a schematic representation of the basic structure of the architecture and overall configuration of a system for graphical monitoring and / or remote control of stationary and / or mobile devices MC from a control center 15 via temporarily switchable radio links 9. The mobile Device MC, which is also referred to below as a mobile controller or as a reporting device MC, ???? The mobile device MC contains three logically separate function blocks BA, BB, BC, which can be combined with one another as required. Function block A comprises the functions for location (eg GPS location), fleet management etc. and has a first interface S1 for driver communication via panel, scanner, etc. Function block BB is used for data acquisition, monitoring and / or alarm output according to predefined rules. Function block BC is used in particular for

Storage of application-specific data of the mobile device MC. Function block BB can be coupled to data sources Q2 ... Q4 via interfaces S2 ... S4. The control center 15 is characterized in that it is able to distinguish three separate logical channels A, B1, B2. These channels A, B1, B2 can also be physically separated, depending on whether the control center has direct access to the radio network via radio modems or whether it is connected via ISDN or the Internet, e.g. with GSM direct access (SMS and GSM data). The control center contains three function blocks, namely a communication server KS and a graphic visualization system VS, and the alarm system AS. These blocks use a subordinate communication system. Channel A is used for communication between the communication server KS and the block BA of the mobile device MC, while the channel B1 is provided for communication between the alarm system AS and the block BB. The channel B2 is used for communication between the visualization system VS and the block BB of the mobile device MC. In the exemplary embodiment shown in FIG. 2, channels A, B1, B2 are implemented via an air interface 9 of a radio link.

The system shown in FIG 2 is based on the PLC technology (PLC = programmable logic controller), which is used in the field of automation technology. The system shown in FIG. 2 is modularly expandable and universal for monitoring, diagnosis, teleservice, GPS location etc., in particular Universally applicable for logistics and fleet management tasks. The control center 15 is implemented, for example, as a WinCC station, ie the control center 15 uses the WinCC system from Siemens as the operator control and monitoring system. The modular architecture of the mobile device MC enables a combination with other software systems in a simple manner. Due to the architecture with the separate function blocks and the separate channels A, Bl, B2, a temporal parallelism of alarm signal, diagnosis and driver communication to the control center is guaranteed.

FIG. 3 shows a schematic illustration for graphic alarm processing by means of a visualization, operating and / or observation system. 3 shows the basic functional blocks of the mobile device MC and central unit 15. The mobile device MC is a mobile controller with a certain unique identifier K, in the present case with the control ID44. This identifier is stored in the mobile controller MC and is transmitted to the control center 15 via the radio interface 9. The control center 15 contains a communication driver 19, for example a so-called radio DLL 19 (DLL = Dynamic Link Library. The radio DLL is used to manage the subscribers, ie the mobile devices MC managed in the control center 15 and to integrate the subscriber-specific data in user-specific image dialogs 20, which are coupled to data archives 25. After an alarm message 18 arrives from the mobile controller MCI at the control center 15, the radio DLL 19 sends the received alarm message into an alarm window 1 as message M2 via means 8 for setting up an alarm message The alarm window 1 consists of rows and columns, each row being assigned a message M1, M2, and the columns contain data associated with the respective messages M1, M2, which is the alarm identifier in the alarm window 1 shown in FIG. the date, the time, the vehicle registration number, the control identification, the error description and the duration of the F that occurred ehlers. The user in the control center 15 can initiate an automatic selection 24 of the control center at the mobile controller MC based on the message M2 visualized in the alarm window 1 by triggering a step 4 in the form of a double click with the aid of the PC mouse on the message line of the message M2 via an access step 3 in a telephone book 2 . As a result, a radio connection to the associated MCI mobile controller is established immediately after user operation by double-clicking on the selection of the alarm message M2 or by pressing a button. In the following, this is also referred to as implicit controller selection. An explicit controller selection is alternatively possible through process step 5. In this case, an implicit controller selection is made possible from the telephone book 2 based on the identifiers for the MCI ... MC4 mobile controllers and the associated attributes, such as identifier, manufacturer and assigned radio link in the form of the assigned telephone number. The selection and operation of the radio link is carried out by a specific driver, for example in the form of the radio DLL 19. This driver handles all communication with the MCI ... MC4 controller.

The invention is intended to enable the parallel operation of monitoring / diagnostic / teleservice and tele-maintenance with GPS location, transport and logistics or fleet and fleet management tasks in a system and a single mobile controller. An application consists of one or more mobile controllers (1 controller per vehicle) and one or more WinCC control centers. The controller can be used for individual tasks or for a combination of these tasks. The mobile controller and the WinCC

Head office can be used universally and in larger quantities on the market. The integration of signal / measured value acquisition and processing in a mobile controller (on-board computer) results in an additional economic benefit for a customer through the integrated early detection of errors in vehicles or load monitoring and by minimizing service / workshop trips. So far, there has been no open and expandable standard software solution for the head office on the market for vehicle / load monitoring and the monitoring of construction machinery or remote machines that are operated without PLC technology. So far there is on the mobile devices page

• PLC solutions that are not particularly suitable for monitoring and diagnostics in the mobile area. There is no sophisticated, robust automatic alarm system from

Field to the headquarters as well as real-time measurement options.

• no modular and combinable controllers on the market that can be used universally. Instead, devices specialized for each application, e.g. PLC, GPS

Locating devices, fleet management devices or single-purpose in-house developments by the machine builders for the teleservice.

• no universal monitoring and diagnostic devices on the market that can be used for construction machinery and commercial vehicles or in the outdoor area for machine monitoring. There were expensive special solutions e.g. in the turbine and power plant sector. The control center is implemented as a WinCC station. For fleet management / transport and logistics tasks or for GPS location (via map software), a software system that is commercially available, e.g. FAP (Fleet Application Protocol) compliant. This makes it possible in connection with the invention, without expensive in-house development of such software (e.g. MAP & GUIDE) from

Market. WinCC can therefore also be used in the forwarding area or for fleet monitoring. All sensor / actuator-related automatic monitoring and processing is handled logically separately in the interaction between the controller and WinCC.

The special features of the invention are: • Architecture that allows a combination of WinCC with other software systems from the market.

• Architecture is also universal for future self-monitoring and remote diagnosis tasks on vehicles such as Cars, commercial vehicles, construction machinery.

• Architecture guarantees temporal parallelism from the alarm channel to the control center and teleservice function to individual / multiple mobile controllers.

• Real-time data recording and evaluation on site, even over slow (radio) lines, is carried out using a data analyzer.

Function possible (comparable to digital oscillograph function).

• Alarm system based on WinCC with "1-Click" selection for monitoring / teleservice operation • Alarm system with automatic acknowledgment after successful alarm archiving in the control center, as well as automatic repetition of the alarm transmission for unsecured radio networks (SMS) for robust and operatorless operation

• Dynamically adapting alarm system on a mobile controller to prevent the alarm from being flooded with the same recurring alarm messages.

• WinCC with GPS theft monitoring / alarm

The architecture described is designed for use over radio links, e.g. Mobile networks such as GSM, GPRS, UMTS etc., via satellite radio, via "short-range radio". It is also characterized in that the application solution remains neutral regardless of the implementation of the services, protocol stacks, which are superimposed on the networks.

The configuration basically consists of a control center and several mobile controllers, which are temporarily connected via a radio link.

The architecture of the signaling device MC (= Mobile Controller) offers the special feature that one and the same controller for pure monitoring tasks of mobile or stationary measurement devices machines, construction machinery, vehicles up to applications in transport and logistics. For this purpose, the "Controller" device in combination with a multitasking operating system combines three logically separate function blocks A, B and C, which can be combined with each other as required.

The function block BA (FIG. 2) comprises the functions for location (e.g. GPS), fleet management etc. It is characterized by interactions with the driver via various input options.

The logically separated block BB takes over all automatically running tasks regarding the monitoring and control of all sensors, actuators and vehicle bus systems (e.g. CAN) or fieldbus. Its hallmarks are its alarm system, measured value acquisition, preprocessing and storage with, for example: Data logger, data analyzer, classification function, limit value monitoring.

The data analyzer is characterized in that, in conjunction with a high signal sampling rate of all signal inputs and the objects on the bus systems, it allows very fast measurement sequences of signals that belong together with precise date and time stamping. The complete recorded data block consisting of several data records can be made graphically visible with high temporal resolution after transmission to the central office. This ensures the measurement acquisition and processing of signals in the MC that would otherwise not be observable in real time via the radio link from the control center.

The special feature of the alarm system is the security of the message transmission to the control center. Alarm, fault and warning messages are generated in the controller when defined signal states are reached or external signals are exceeded. When they occur, these are buffered in a spool system of the controller. Successively the controller sends these alarms to the control center by radio. The control center must automatically acknowledge each message individually after receipt and archiving by a logical acknowledgment to the controller. Only then is the transmitted message deleted in the controller (in the spool). If sent messages are not acknowledged by the control center within an adjustable time, the controller repeats the transmission of the corresponding message.

The block BC contains diagnostics as well as upload and download functions for the device software of the controller itself, as well as the application-specific programs, parameters and data records.

The control center is characterized in that it distinguishes three separate logical channels. Depending on whether the control center has direct access to the radio network via radio modems or is connected via ISDN or the Internet, these channels can also be physically separated, e.g. with GSM direct access (SMS and GSM data).

All communication regarding channel A Location and fleet management. The communication server takes over the distribution function for applications based on FAP (Fleet Application Protocol).

All communication between the alarm system and the graphic visualization system in the control center runs via channel B1 as the "alarm channel" either via the communication server

(Connection V) or directly to WinCC. This offers the advantage of multiple applications such as Fleet management and vehicle, load, machine monitoring, teleservice etc. to integrate in a control center.

The visualization system uses a separate channel B2 in order to provide services with high data volume and / or time handle requirements. In parallel, however, even if B2 is blocked by a permanent direct radio connection, all alarm messages from the field via channel A can still reach the control center undisturbed.

The alarm window FIG. 3 shows the alarm, warning or fault messages arriving from the field by individual or several controllers. The structure within the alarm window is row or column oriented. In order to implement a multilingual user interface (can be set individually for each work station) and to reduce the data to be transmitted, only the alarm-relevant data such as alarm / fault detection, the date and time of the triggering event, its duration and any additional parameters are transmitted to the control center via radio.

In order to identify a mobile device or vehicle, a unique identifier (e.g. controller ID or serial / chassis number) must also be transmitted.

The data transmitted in this way are received in the

Control center translated into language-specific plain text messages using a table structure. This table (possibly also several) contains a translation as plain text for each identifier for each language used. The same applies to the format implementation of country / language typical formats or notations such as Time / date and additional parameters. The actual messages are then compiled from this, entered in the alarm archive and displayed in succession in the alarm window.

The visible content of the alarm window is limited to a finite number of alarm / warning and fault messages. Therefore, the operator can use the slider (26) or up / down buttons to move the visible alarm window section over all saved messages. In order to find out the reason for an alarm, warning or fault message arriving from a mobile controller, there is the option of directly selecting the corresponding controller by radio using minimal operating steps, in order to read further details from the controller via teleservice or for diagnosis or remote maintenance perform. For this purpose, it is sufficient to mark the corresponding message in the alarm window with a mouse click or with the cursor. The radio connection to the associated mobile controller is established immediately afterwards by double-clicking or pressing a button, see Implicit controller selection.

A telephone book or a database is used to manage all information on how each controller can be reached in the field: e.g. the communication service, addresses or subscriber number e.g. Mobile number. Additional information serves to make it easier for an operator to find; for him It is easier to find and select an official vehicle registration number than a controller ID. By selecting a phone book entry and double-clicking or pressing a button, an operator can explicitly select a controller.

In contrast to the explicit controller selection, with the implicit controller selection, the radio connection to the associated controller is established by double-clicking on a message in the alarm window. With a double click, the associated program takes the unique identifier with regard to the controller ID and determines all the data required for the selection from the above. Database. The order block for the selection of the controller is built from this. The selection and operation of the

A specific driver takes over the radio link (e.g. DLL Data Link Library). This driver handles all communication with the controllers in the field. It offers a program interface for any user program as well as for all subsequent screen dialog programs. This is also used, for example, to download software to the controller. The image dialogs are also supplied with the necessary data from the controller via the driver. For the purpose of optimizing radio communication and in the sense of a quick screen setup, only those data from the controller can be selectively requested and loaded into the control center that are required for the respective function or image. The selection can also mean different time cycles for the update of each individual data field. This is independent of the type and medium of transmission, this is ensured by the specific driver (s).

The image dialogs are designed depending on the respective application. These can have write and read access to the controller. The data read from a controller into the control center are written to files via the image dialogs for archiving.

Further explanations regarding the execution of the alarm system are given below: Faults are informed. In order to take account of the system's inherent unreliability of the communication route, functions are required for storing the events that have occurred on the mobile system up to central archiving on the B&B station. In order to prevent the alarm archive from being overwhelmed due to the same events or alarms, it must be possible to limit the same entries. This also serves to minimize transmission costs.

The Mobile Controller implements a retentive alarm archive to solve these requirements. Various retentive media such as battery-backed RAM, flash EPROM, E ² PROM ... can be used for this. The number of entries in the same alarm message can be limited by configuration. Firstly, in the case of faulty signals, which lead to the recurring triggering of the alarm message, or to prevent the alarm archive from becoming blocked in the event of long-term failures in the communication link.

The mobile system sends an alarm message that has just been entered in the controller as soon as a communication order can be placed. An alarm message is only sent to the controller when a logical acknowledgment from the recipient of the alarm message, i.e. e.g. the head office that arrives at the controller. This receipt can arrive immediately or with a delay due to the medium or service. Logical or physical connections can be used (e.g. serial, also streamed or packetized, e.g. data transmission via IP, GSM, GPRS, or other transmission protocol or service). If an acknowledgment from the recipient of an alarm message does not arrive within a configurable time, a new attempt to send is started. On the part of the recipient (e.g. control center with WinCC), the acknowledgment of an alarm message is automatically sent to the mobile system after it has been archived. If an alarm message in the controller reaches the configured number of maximum identical messages, this will be noted in the next alarm message sent. Acknowledgments that arrive later no longer remove the entry lock for this alarm message, in order to prevent an unnecessarily high number of messages on the route to the control center. This entry block can only be removed by a special order. This behavior can be switched over or switched off in the alarm system. At the control center, the overflow of this alarm message is signaled to the operator by suitable means. Functions for triggering the release order for the previously set entry block are available to the user.

In one embodiment of the alarm system, the alarm archive is implemented in the battery-buffered RAM. The alarm messages are transmitted to WinCC via GSM SMS. After an entry in the WinCC archive (= persistent storage), WinCC sent a receipt back to the sender via GSM-SMS. Alarm messages that have reached the entry limit are specially highlighted. The WinCC user has a dialog for reading all overflowed alarm messages with the subsequent release option.

In summary, the invention thus relates to a system and a method for, in particular, graphic monitoring and / or remote control of stationary and / or mobile devices FL.Fn, in particular of vehicles, construction machines and / or

Containers, by means of a reporting device MC from a control center 15, the mobile device MC having a first function block BB for recording measured values, for monitoring and / or for issuing alarms according to predefinable rules and a second function block BC for storing application-specific data of the mobile device MC and the center 15 and the mobile device MC have means for communication via at least two communication channels B1, B2, the first communication channel B1 for communication between a communication server KS of the center 15 and the second function block BB of the mobile device MC and the second communication channel B2 for communication between a visualization system VS of the control center 15 and the second function block BB of the mobile device MC are provided.

Claims

claims

1. System for in particular graphic monitoring and / or remote control of stationary and / or mobile devices (FL.Fn), in particular vehicles (FL.Fn), truck trailers, construction machinery, agricultural vehicles, swap bodies and / or containers, by means of a Signaling device (MC) from a control center (15), the mobile device (MC) having a first function block (BB) for recording measured values, for monitoring and / or for issuing alarms according to predefined rules and a second function block (BC) for storing Application-specific data of the mobile device (MC) and wherein the center (15) and the mobile device (MC) has means for communication via at least two communication channels (B1, B2), the first communication channel (B1) for communication between one Alarm system (AS) and / or a communication server (KS) the center (15) and the second function block (BB) of the mobile device (MC) and the second commun ikationskanal (B2) for communication between a visualization system (VS) of the center (15) and the second function block (BB) of the mobile device (MC) are provided.

2. System according to claim 1, so that the mobile device (MC) has at least one radio transceiver for the temporary connection with at least one center (15) and / or with a subscriber (E) authorized to receive messages.

3. System according to one of claims 1 or 2, characterized in that the mobile device (MC) has a third function block (BA) which includes functions for location and / or fleet and / or fleet management and the means for commu- nication with a user at the location of the mobile device

(MC).

4. System according to any one of claims 1 to 3, characterized in that the mobile device (MC) has a data analyzer integrated in particular in the first function block (BB), which for recording predeterminable measuring sequences by scanning the data analyzer via signal sources (Q1 ..Q4) supplied input signals (E1..E4) it is provided that the mobile device is provided for stamping the recorded data signals with a date and time stamp and that the mobile device (MC) for transmitting the scanned data sets to the control center (15 ) is provided for graphic display within an operating and monitoring system.

5. System according to one of claims 1 to 4, so that the mobile device (MC) has an alarm system integrated in particular in the first function block (BB), which is provided for the transmission of alarm messages according to predefinable rules and for securing the transmitted messages.

6. System according to any one of claims 1 to 5, characterized in that the alarm system for storing alarm messages in the mobile device (MC), for sending the alarm message to a predeterminable center (15) and for monitoring an acknowledgment of the alarm messages sent by the center (15) is provided.

7. System according to any one of claims 1 to 6, characterized in that the application-specific data and programs that can be stored in the second function block (BC) can be loaded remotely from a control center (15).

8. System according to any one of claims 1 to 7, characterized in that the center (15) and the mobile device (MC) have means for communication via a third communication channel (A), the third communication channel (A) in particular for communication between the communication server (KS) of the center and the third block (BA) of the mobile device (MC) is provided.

9. System according to any one of claims 1 to 8, characterized in that the mobile signaling device (MC) is assigned an identifier (K) for identifying the mobile device (MC), that the mobile signaling device means for transmitting the identifier to the center (15) together with a message and that the center (15) has means for storing and visualizing the identifier.

10. System according to one of claims 1 to 9, characterized in that the visualization system and / or the control and monitoring system (VS) has an alarm window (1) for the optical visualization of messages, in particular alarm, warning and / or fault messages that the alarm window has information for identifying the message, in particular the identifier, date, time and a description of the error.

11. System according to one of claims 1 to 10, characterized in that the visualization system and / or the operating and observation system of the center (15) means for an implicit Selection of a mobile device (MC) assigned to a message (Ml, M2) in such a way that by selecting a message (Ml, M2) from a message table (1), in particular by double-clicking or by pressing an input function, the selected message is automatically sent (Ml, M2) associated mobile device (MC) is selected for establishing a connection.

12. System according to any one of claims 1 to 11, characterized in that the visualization system and / or the control and monitoring system of the center (15) has a telephone book window (2) for visualization of each of a central (15) managed mobile reporting devices (MC) having.

13. System according to one of claims 1 to 12, characterized in that the visualization system and / or the control and monitoring system of the center (15) has means for an explicit selection of a mobile device (MC) in such a way that by selecting a mobile Device (MCI..MC4) from the phone book table (2), in particular by double-clicking or by actuating an input function, the selected mobile device (MCI..MC4) is automatically selected for establishing a connection.

14. System according to one of claims 1 to 13, that the central unit has means for storing the data transmitted from the mobile signaling device (MC) to the central unit (15) for archiving the data.

15. System according to any one of claims 1 to 14, characterized in that the reporting device (MC) has a GPS module for locating a mobile device coupled to the reporting device (MC), the reporting device (MC) for transmitting the

Location data to the control center (15) is provided.

16. A method for, in particular, graphic monitoring and / or remote control of stationary and / or mobile devices (FL.Fn) which can be coupled to a signaling device (MC), in particular of vehicles, construction machinery and / or containers, from a control center (15), wherein the mobile device (MC) has a first function block (BB) for recording measured values, for monitoring and / or for issuing alarms according to predefinable rules and a second function block (BC) for storing application-specific data of the mobile device (MC), and the center (15 ) and the mobile device (MC) has means for communication via at least two communication channels (B1, B2), the first communication channel (B1) for communication between an alarm system and / or a communication system (KS) of the control center (15) and the second Function block (BB) of the mobile device (MC) and the second communication channel (B2) for communication between a visualization system tem (VS) of the center (15) and the second function block (BB) of the mobile device (MC) are provided.

17. Notification device (MC) for a system for in particular graphic monitoring and / or remote control of stationary and / or mobile devices (FL.Fn), in particular vehicles (FL.Fn), construction machinery and / or containers, by means of the notification device (MC ) from a control center (15), the mobile device (MC) having a first function block (BB) for recording measured values, for monitoring and / or alarming according to predefinable rules and a second function block (BC) for storing application-specific data of the Mobile device (MC) and wherein the center (15) and the mobile device (MC) has means for communication via at least two communication channels (B1, B2), the first communication channel (B1) for communication between an alarm system and communication system (KS) of the control center (15) and the second function block (BB) of the mobile device (MC) and the second communication channel (B2) for communication between a visualization system (VS) of the control center (15) and the second function block (BB) of the mobile device (MC) are provided.

18. Visualization, operating and / or observation system for a system for, in particular, graphic monitoring and / or remote control of stationary and / or mobile devices (FL.Fn), in particular vehicles (FL.Fn), construction machines and / or containers, by means of a signaling device (MC) from a control center (15), the mobile device (MC) having a first function block (BB) for recording measured values, for monitoring and / or for issuing alarms according to predefinable rules and a second function block (BC) for storing Application-specific data of the mobile device (MC) and wherein the center (15) and the mobile device (MC) has means for communication via at least two communication channels (B1, B2), the first communication channel (B1) for communication between the alarm system and / or a communication system (KS) of the center (15) and the second function block (BB) of the mobile device (MC) and the second communication channel (B2) for communication between a visualization system (VS) of the control center (15) and the second function block (BB) of the mobile device (MC) are provided.

19. Computer-readable medium, in particular CD, diskette, for a system for, in particular, graphic monitoring and / or

Remote control of stationary and / or mobile devices (FL.Fn), in particular of vehicles (FL.Fn), construction machines and / or containers, by means of a signaling device (MC) from a control center (15), the mobile device (MC) a first function block (BB) for data acquisition, for

Monitoring and / or for alarm output according to predefinable rules and a second function block (BC) for storing incoming Application-specific data of the mobile device (MC) and wherein the center (15) and the mobile device (MC) has means for communication via at least two communication channels (B1, B2), the first communication channel (B1) for communication between the alarm system and / or communication system (KS) of the center (15) and the second function block (BB) of the mobile device (MC) and the second communication channel (B2) for communication between a visualization system (VS) of the center (15) and the second function block ( BB) of the mobile device (MC) are provided.

20. Program module, in particular for remote charging via the Internet, for a system for, in particular, graphic monitoring and / or remote control of stationary and / or mobile devices (FL.Fn), in particular vehicles (FL.Fn), construction machines and / or containers, by means of a signaling device (MC) from a control center (15), the mobile device (MC) having a first function block (BB) for recording measured values, for monitoring and / or for issuing alarms according to predefinable rules and a second function block (BC) for storing of application-specific data of the mobile device (MC) and wherein the center (15) and the mobile device (MC) have means for communication via at least two communication channels (B1, B2), the first communication channel (B1) for communication between Alarm system and / or communication system (KS) of the control center (15) and the second function block (BB) of the mobile device (MC) and the second communication channel l (B2) for communication between a visualization system (VS) of the center (15) and the second function block (BB) of the mobile device (MC) are provided.