EP4022641A1 - Method and system for efficiently operating laboratory measuring equipment - Google Patents

Abstract

A computer-implemented method for efficiently operating laboratory measuring equipment (4) of a laboratory measuring equipment operator (LMGB), having the steps of: - receiving (S1) laboratory equipment data that are output by various types of laboratory measuring equipment (4) of the laboratory measuring equipment operator (LMGB) in different output data formats; – converting (S2) the received laboratory equipment data into at least one prescribed target data format of a laboratory information and management system, LIMS, (5) of the laboratory measuring equipment operator (LMGB), wherein data fields of the output data formats are automatically converted to data fields of the target data format in accordance with mapping information stored for the laboratory measuring equipment operator (LMGB); writing (S3) the converted laboratory equipment data in the target data format into a laboratory database (6) of the laboratory information and management system, LIMS, (5) of the laboratory measuring equipment operator (LMGB), wherein the laboratory measuring equipment of the laboratory measuring equipment operator (LMGB) communicates with the laboratory information and management system, LIMS, (5) of the laboratory measuring equipment operator (LMGB) to increase the overall utilization of the laboratory measuring equipment (4) of the laboratory measuring equipment operator (LMGB).

Description

Process and system for the efficient operation of laboratory measuring devices

The invention relates to a method and a system for the effi cient operation of laboratory measuring devices of an operator of laboratory measuring devices (laboratory measuring device operator, LMGB), in particular an efficient operation of thermoanalytical laboratory measuring devices. The overall utilization of the laboratory measuring devices is increased and the flexibility in operating the laboratory measuring devices is increased.

The term thermal analysis refers to any measuring method in which a material sample, which can be of known or unknown composition or nature, is subjected to a temperature change in a controlled manner, with one or more physical variables on the material being sampled at the same time during this temperature control measured and recorded as a temperature-dependent measurement signal.

Such laboratory measuring devices can be used to determine thermophysical properties of material samples. The physical and chemical properties of materials change under the influence of temperature, atmosphere and pressure. In addition to the investigation of thermophysical properties, laboratory measuring devices can be used to track the curing process, dynamic mechanical analysis and calorimetry. The laboratory measuring devices allow a material characterization as well as a determination of the specific heat capacity, enthalpy, mass change, the modulus of elasticity, the thermal expansion and shrinkage, the temperature and thermal conductivity as well as an analysis of the released gases, for example during a thermal decomposition. settlement. From this, conclusions can be drawn about the purity and composition of materials, their thermal stability and their temperature limits in various applications. Furthermore, aging processes, the thermomechanical behavior and viscoelastic properties of the materials can be determined. A material sample of the material to be examined is preferably used for the examination in a heating furnace with which the material sample is heated, with various types of sensors generating measurement data. The recorded measured variables include, for example, the expansion behavior, changes in weight and phase transition temperatures or changes in enthalpy of the sample during the measurement process.

There are a large number of different types of laboratory measuring devices that are manufactured by different manufacturers of laboratory measuring devices. A laboratory measuring device operator therefore usually uses a large number of heterogeneous laboratory measuring devices of the most varied types, which are produced by different laboratory measuring device manufacturers, to carry out different measurements on one or more material samples. The laboratory measuring devices of a laboratory measuring device operator can be located at a central location or distributed across different locations. The various laboratory measuring devices of a laboratory measuring device operator can be located in a measuring laboratory and / or in the vicinity of a production plant. The measurement samples are taken, for example, in a production process and fed to one or more laboratory measuring devices for analysis. The material samples can, for example, be taken manually from the production chain and introduced into the heating furnace of the respective laboratory measuring device. In many cases it is also possible to have the measurement samples automatically in a production stage of the production plant to be removed and fed into a heating furnace of the laboratory measuring device or testing device for carrying out analytical tests. A large number of laboratory measuring devices from a laboratory measuring device operator can deliver a large amount of laboratory device data in different data formats. Laboratory measuring device operators use laboratory information and management systems (LIMS) to manage and analyze the large number of laboratory device data obtained. These laboratory information and management systems support the processing of the various material samples and save the resulting data in a structured, evaluable form in a database. There are many different providers of laboratory information and management systems. As a rule, a laboratory measuring device operator uses a laboratory information and management system from a specific provider. LIMS-capable laboratory measuring devices or instruments can store their laboratory device data as a data record in files so that they can be processed by applications. The laboratory information and management systems of the various providers have import interfaces that support common file formats for reading in structured data. However, laboratory measuring device operators mostly use laboratory measuring devices from different manufacturers and different types in different variants. In many cases it is therefore not possible to connect all laboratory measuring devices of a laboratory measuring device operator to the laboratory information and management system (LIMS) used by the laboratory measuring device operator. Furthermore, in many cases it is not possible to simply replace a laboratory measuring device of a certain type or manufacturer with another laboratory measuring device of a different type or manufacturer. Since laboratory measuring devices of different types or different manufacturers use differently structured data formats, it is also Exchange of a laboratory measuring device by another laboratory measuring device is not possible to update the inventory data in the LIMS. This makes it difficult, if not impossible, to replace a laboratory measuring device with that of another manufacturer. The laboratory measuring device operator who operates a large number of different laboratory measuring devices therefore has very little flexibility to expand his existing fleet of laboratory measuring devices or to replace a laboratory measuring device with another laboratory measuring device from another or new manufacturer. In particular, cross-manufacturer networking of laboratory measuring devices with the laboratory information and management system (LIMS) used by the laboratory measuring device operator is also not possible. In the case of laboratory measuring devices of the laboratory measuring device operator, which cannot be connected to the laboratory information and management system of the laboratory measuring device operator, it is also necessary to carry out the data management manually. This leads to a considerable amount of work and a considerable delay in the analysis of the material samples. Due to the lack of connection to at least some of the laboratory measuring devices of the laboratory measuring device operator, it is not possible to plan the capacity and utilization of the various laboratory measuring devices for examining different material samples. This leads to a relatively low utilization of the various laboratory measuring devices of the laboratory measuring device operator.

It is therefore the object of the present invention to drive a method and create a system which avoids the above-mentioned disadvantages of conventional systems and allows laboratory measuring devices of a laboratory measuring device operator to be operated more efficiently and flexibly. This object is achieved according to the invention by a computer-implemented method for the efficient operation of laboratory measuring devices of a laboratory measuring device operator with the features specified in claim 1.

According to a first aspect, the invention creates a computer-implemented method for the efficient operation of laboratory measuring devices of a laboratory measuring device operator with the following steps:

^ Receipt of laboratory device data, which are output by different types of laboratory measuring devices of the laboratory measuring device operator in different output data formats,

> Conversion of the received laboratory device data into at least one specified target data format of a laboratory information and management system of the laboratory measuring device operator, with data fields of the output data formats being automatically converted or mapped to data fields of the target data format in accordance with mapping information stored for the laboratory measuring device operator become,

^ Writing the converted laboratory device data in the target data format into a laboratory database of the laboratory information and management system (LIMS) of the laboratory measuring device operator, whereby the laboratory measuring devices of the laboratory measuring device operator (LMGB) with the laboratory information and management system (LIMS) of the laboratory measuring device operator ( LMGB) to increase the overall utilization of the laboratory measuring devices of the laboratory measuring device operator (LMGB).

With the help of the method according to the invention, it is possible to exchange or replace laboratory measuring devices, so that the Flexibility to operate different laboratory measuring devices (different types and / or different manufacturers) is significantly increased. This increases the efficiency when operating different laboratory measuring devices, ie in particular also the number of samples examined per time.

A laboratory information and management system (LIMS) within the meaning of this invention can be programs specially developed for this purpose that are designed purely for use in a laboratory or for production control. On the other hand, laboratory information and management systems (LIMS) can simply be databases or any other type of software solution that is suitable for processing, evaluating or transmitting data. Such programs can also be CRM tools, for example, in which customer data on the sales side is processed and linked to measurement data from measuring devices by means of the system according to the invention. This list is not exhaustive and is not intended to restrict the invention to specific software solutions.

The focus of the method and system according to the invention is placed on laboratory measuring devices. These are not intended to limit the invention. It is clear to a person skilled in the art that the method according to the invention and the system according to the invention can also be used in production control or in all areas in which data and / or measured values have to be converted by a device for a database and / or an evaluation tool.

In one possible embodiment, the respective utilization of the various types of laboratory measuring devices of the laboratory measuring device operator is based on the data in the target data format of the store. bor information and management system of the laboratory measuring device operator determines converted laboratory device data.

In one possible embodiment, the laboratory measuring devices of the laboratory measuring device operator are controlled in order to increase the total utilization of the laboratory measuring devices as a function of the determined utilization of the laboratory measuring devices of the laboratory measuring device operator.

In a possible embodiment of the computer-implemented method according to the invention, the laboratory device data of the laboratory measuring device have master data of the laboratory measuring device, measurement data of the laboratory measuring device and / or operating status data of the laboratory measuring device.

In a further possible embodiment of the computer-implemented method according to the invention, the various laboratory measuring devices from the laboratory measuring device operator include laboratory measuring devices from different laboratory measuring device manufacturers and / or different laboratory measuring device types that generate measurement data and output them in defined output data formats. Since there are different laboratory measuring devices or laboratory measuring device types from different laboratory measuring device manufacturers, the defined output data formats can be different.

In a further possible embodiment of the computer-implemented method according to the invention, the output data formats contain structured data records with data fields for different measurement parameters and / or master data types. In a further possible embodiment of the computer-implemented method according to the invention, the mapping information of the laboratory measuring device operator is stored in a configurable mapping table which assigns a data field of the target data format of the laboratory information and management system of the laboratory measuring device operator to each data field of an output data format.

In a further possible embodiment of the computer-implemented method according to the invention, the laboratory device data contained within a data field of the output data format are imported, in particular copied, into the assigned data field of the target data format of the laboratory information and management system of the laboratory measuring device operator during the conversion.

In a further possible embodiment of the computer-implemented method according to the invention, the mapping information contained in the mapping table of the laboratory measuring device operator is processed in a configuration routine and / or automatically updated during operation of the laboratory measuring device.

In a further possible embodiment of the computer-implemented method according to the invention, the laboratory device data of the laboratory measuring device stored in the laboratory database in the target data format of the laboratory information and management system of the laboratory measuring device operator can be used in response to a control command for reconversion into the output data format according to the in The mapping information stored in the mapping table of the laboratory measuring device operator can be converted back. In a further possible embodiment of the computer-implemented method according to the invention, the output and target data have the following formats: a CSV data format, an INI data format, an XML data format, an ODS data format, an ODT data format, a JSON data format , an RSS data format, an RDF data format, a TXT data format, and a TDMS data format. This list is not exhaustive. It is clear to a person skilled in the art that all known data formats can be converted and mapped and thus made accessible for any laboratory information and management system. The previous list only includes the most popular data formats.

In a further possible embodiment of the computer-implemented method according to the invention, the laboratory measuring devices of the laboratory measuring device operator have material testing devices for performing measurements on material samples, the measurement data generated thereby being output in an output data format via a data interface of the laboratory measuring device.

In a further possible embodiment of the computer-implemented method according to the invention, a control of the laboratory measuring device of the laboratory measuring device operator receives control commands with measurement specifications for carrying out measurements on material samples from the laboratory information and management system of the laboratory measuring device operator during operation.

In a further possible embodiment of the computer-implemented method according to the invention, the laboratory measuring device of the laboratory measuring device operator transmits laboratory device data provided as a client in an output data format of the Laboratory measuring device, which is transmitted as user data in data packets via a data network to a local or external (remote) server, which executes a server application that automatically transfers the received laboratory device data from the laboratory measuring device to the specified target in accordance with the mapping information stored for the laboratory measuring device operator -Data format of the laboratory information and management system of the laboratory measuring device operator converted.

In a further possible embodiment of the computer-implemented method according to the invention, when a first laboratory measuring device from a specific laboratory measuring device manufacturer and / or a specific laboratory measuring device type is replaced by a second laboratory measuring device from another laboratory measuring device manufacturer and / or another laboratory measuring device type, the data in the laboratory database of the laboratory Information and management system of the laboratory measuring device operator in the target data format stored laboratory device data of the first laboratory measuring device automatically updated seamlessly with laboratory device data of the second laboratory measuring device in the target data format.

In a further possible embodiment of the computer-implemented method according to the invention, there is a bidirectional communication connection for exchanging laboratory device data and control commands between the laboratory measuring device of the laboratory measuring device operator and the laboratory information and management system of the laboratory measuring device operator during operation of a laboratory measuring device.

The bidirectional communication link comprises a direct communication link or an indirect communication link via a conversion device. In a further possible embodiment of the computer-implemented method according to the invention, the exchange of the laboratory device data and the control commands takes place in real time via the bidirectional communication connection existing between the laboratory measuring device and the laboratory information and management system.

According to a further aspect, the invention creates a system for the efficient operation of laboratory measuring devices of a laboratory measuring device operator with the features indicated in claim 17.

The invention accordingly creates a system for the efficient operation of laboratory measuring devices of a laboratory measuring device operator, the system comprising:

Laboratory measuring devices of the laboratory measuring device operator, which each provide laboratory device data in different output data formats, a conversion device for converting the received laboratory device data into at least one predetermined target data format of a laboratory information and management system of the laboratory measuring device operator, with data fields of the output data formats corresponding to the laboratory measuring device operator in A mapping table of stored mapping information is automatically converted or mapped to data fields of the target data format and the converted laboratory device data is written in the target data format in a laboratory database of the laboratory information and management system of the laboratory measuring device operator, where the laboratory measuring devices of the laboratory measuring device operator ( LMGB) with the laboratory information and management system (LIMS) of the laboratory measuring device operator (LMGB) to increase the overall Communicate the utilization of the laboratory measuring devices of the laboratory measuring device operator (LMGB).

In one possible embodiment of the system, the laboratory information and management system of the laboratory measuring device operator uses the data converted into the target data format of the laboratory information and management system and written into the laboratory database of the laboratory information and management system Laboratory device data is determined and the laboratory measuring devices are controlled by control commands to increase the overall utilization of the laboratory measuring devices of the laboratory measuring device operator, which the laboratory information and management system of the laboratory measuring device operator transmits to the laboratory measuring devices of the laboratory measuring device operator directly or indirectly via a conversion device.

According to a further aspect, the invention also provides a conversion device for automatically converting laboratory device data received in different output data formats into at least one predetermined target data format of a laboratory information and management system of a laboratory measuring device operator, with data fields corresponding to the output data formats in a mapping table The mapping information stored by the laboratory measuring device operator can be automatically mapped to data fields of the target data format.

In one possible embodiment, the conversion device is implemented on a cloud server. It is also possible for the output data to be converted within the laboratory measuring device. In this embodiment of the invention, the laboratory measuring devices of the Laboratory measuring device operator communicate directly with the laboratory information and management system of the laboratory device operator and exchange the necessary data.

The invention also provides a computer program product with stored program instructions for performing a method according to the first aspect of the invention.

In the following, possible embodiments of the computer-implemented method according to the invention and of the system for the efficient operation of laboratory measuring devices of a laboratory measuring device operator are explained in more detail with reference to the figures.

Show it:

1 shows a schematic representation of a possible embodiment of the system according to the invention for the efficient operation of laboratory measuring devices of a laboratory measuring device operator;

Fig. 2 is a flow chart to illustrate a possible embodiment of a computerim plemented method according to the invention for increasing the utilization of laboratory measuring devices of a Labormessgerätebe driver;

3 shows a block diagram of a possible embodiment of a conversion device according to the invention which can be used in the system according to FIG. 1; Fig. 4 is a schematic illustration to explain the

Functioning of the computer-implemented method according to the invention for the efficient operation of laboratory measuring devices of a laboratory measuring device operator;

5 shows a further schematic illustration to explain the mode of operation of the computer-implemented method for the efficient operation of laboratory measuring devices of a laboratory measuring device operator;

6 shows a schematic representation of an application example of a computer-implemented method according to the invention for the efficient operation of laboratory measuring devices of a laboratory measuring device operator.

As can be seen from Fig. 1, a system 1 according to the invention for the efficient operation of laboratory measuring devices 4 of a laboratory measuring device operator LMGB comprises a conversion device 2 for the automatic conversion of received laboratory device data into a target data format of a laboratory information and management system (LIMS) 5 of the laboratory measuring device operator LMGB. The conversion device or conversion device 2 of the system 1 according to the invention can be implemented on a server of a data cloud 3 in one possible embodiment. Here, different laboratory measuring devices 4-1, 4-2, 4-3 ... 4-n of a laboratory measuring device operator LMGBi each provide laboratory device data of the laboratory measuring device 4 as a client in an output data format of the laboratory measuring device 4. Each laboratory measuring device operator LMGBi can have a unique identifier (LMGB-ID). The laboratory measuring devices 4 have, for example, thermoanalytical measuring devices. The conversion device 2 can data laboratory equipment, which of different and different Laboratory measuring devices 4 originate from the laboratory measuring device operator, received in different output data formats, as shown schematically in FIG. 1. In one possible embodiment, the conversion device 2 can be implemented on a local or remote server which executes a server application. The server application automatically converts the laboratory device data received from a laboratory measuring device 4 in a defined output data format into a target data format of a laboratory information and management system (LIMS) 5 of the laboratory measuring device operator LMGB. The computer-implemented conversion device 2 can receive laboratory device data from different laboratory measuring devices 4 from the same or different laboratory measuring device operator LMGB. Each laboratory measuring device operator LMGB manages his data in a laboratory information and management system LIMS of his choice. In the example shown in FIG. 1, a laboratory measuring device operator LMGB can manage and evaluate the laboratory device data originating from his laboratory measuring devices 4 with the aid of a laboratory information and management system LIMS selected by him. For example, a laboratory measuring device operator LMGB can choose between a first laboratory information and management system (LIMS _Ä) 5-1, a second laboratory information and management system (LIMS _B ) 5-2 and a third laboratory information and management system ( LIMSc) 5-3, as shown schematically in FIG. Each of the laboratory information and management systems LIMS preferably has an associated laboratory database 6. In the system 1 shown in FIG. 1, the first laboratory information and management system 5-1, the second laboratory information and management system 5- 2 and the third laboratory information and management system 5-3 via the cloud 3 or the data network with the conversion device 2 verbun. In one possible embodiment, the available different laboratory information and management systems 5-1, 5- 2, 5-3 via associated laboratory databases 6-1, 6-2, 6-3. In one possible embodiment, the conversion device 2 has a microprocessor or an ASIC or an FPGA for performing the mapping.

The conversion device 2, which in a possible further embodiment is implemented on a server, is constructed in a possible implementation according to FIG. 3. The conversion device 2 contains a mapping engine 2A and a configuration data memory 2B. The conversion device 2 has a data interface 2C with one or more ports for receiving laboratory measuring device data which are provided by laboratory measuring devices 4 of the same or different laboratory measuring device operator LMGB.

The conversion device 2 can recognize from which laboratory measuring device operator LMGB the received laboratory measuring device data originate. The identification of the laboratory measuring device operator LMGB takes place in different ways depending on the embodiment. In one embodiment, the Labormessgerätebe drivers LMGB are connected to an associated port of the conversion device 2 via a gateway of the LMGB, ie the conversion device 2 uses a port number to identify from which LMGB the received laboratory measuring device data originate. Alternatively, received data packets DP which contain laboratory measuring device data as useful data can have a data field in their header data for specifying the laboratory measuring device operator LMGB (LMGB-ID). Furthermore, in a further embodiment, the laboratory measuring device 4 and its laboratory measuring device operator LMGB can be identified by the conversion device 2 on the basis of a source address in the header of the received data packet DP. Alternatively, in a handshake procedure, the conversion device 2 can also use the ID Query activity of the laboratory measuring device operator LMGB and / or the type of laboratory measuring device 4, for example by means of a corresponding request to a gateway of the laboratory measuring device operator LMGB. The mapping table MT of the identified laboratory measuring device operator LMGB is used by the mapping engine 2A to convert or reformatting the output data format of the received laboratory device data into the target data format of the LIMS of the laboratory measuring device operator LMGB. In addition, the conversion device 2 has a cloud connector interface 2D in connection with the cloud 3, as shown in FIG. 1. The mapping engine 2A of the conversion device 2 is designed to automatically convert the laboratory device data received in output data formats into a predetermined target data format of the laboratory information and management system LIMS used by the laboratory measuring device operator LMGB. In one possible embodiment, the LMGB can define a target data format. For this purpose, the mapping engine 2A of the conversion device 2 has access to the configuration data memory 2B, in which there is an associated mapping table MT for each laboratory measuring device operator LMGB. For example, M mapping tables MT for M different laboratory measuring device operators LMGB are located in the configuration memory 2B. LMGB mapping information is stored in the mapping tables MT for each laboratory measuring device operator. Data fields of the laboratory device data received in the output data formats are automatically transferred by the Mapping Engine 2A to data fields of the target data format of the laboratory information and management system LIMS used by the laboratory measuring device operator LMGB in accordance with the mapping information stored in the mapping table MT of the respective laboratory measuring device operator LMGB - maps or converts. For this purpose, during the conversion process, the data within a data field of the output Laboratory equipment data contained in the data formats are imported into the assigned data field of the target data format by the mapping engine 2A, in particular copied. The laboratory device data include the master data of the laboratory measuring device 4 as well as the measurement data generated by the laboratory measuring device 4. The laboratory device data can also include status data or operating status data of the laboratory measuring device 4, which indicate a current operating status and / or operating mode of the laboratory measuring device 4.

The laboratory device data of a laboratory measuring device 4 contain, for example, information regarding the material sample measured by it, in particular a material sample ID (Sample ID). Further material sample information data include, for example, the density of the material sample P, its mass and its volume. The master data of the laboratory measuring device 4 include, for example, a serial number of the laboratory measuring device 4 and a type designation of the laboratory measuring device 4. The status data or status data can, for example, indicate the test conditions. The measurement data generated by the laboratory measuring device 4 can relate to various measurement parameters, for example a measured temperature, a heat flow (W / m ² ), a thermal conductivity (W / mK), a measured thermal resistance, a measured temperature gradient, a measurement duration or a pressure (kPa). The number and type of measurement parameters measured can vary greatly with different laboratory measuring devices 4. The different types of laboratory measuring devices 4 of a laboratory measuring device operator LMGB include laboratory measuring devices 4 from different laboratory measuring device manufacturers and / or different types of laboratory measuring devices. The output data formats of the laboratory measuring devices 4 preferably have structured data records that contain data fields, a data field being available for each measurement parameter and / or each master data type. can be seen. The mapping information of a laboratory measuring device operator LMGB is stored in the configurable mapping table MT of the laboratory measuring device operator LMGB.

The mapping table MT of the laboratory measuring device operator LMGB assigns a data field of a target data format of the laboratory information and management system LIMS of the laboratory measuring device operator LMGB to each data field of an output data format. This is also shown by way of example in FIGS. 4, 5. The Mapping Engine 2A outputs the converted laboratory device data in the target data format via the 2D cloud interface. The 2D cloud interface forms a logical interface on the transport level to the LIMS systems. The converted laboratory device data are written in the target data format into the laboratory database 6-i of the laboratory information and management system 5-i of the laboratory measuring device operator LMGB. For this purpose, the converted laboratory device data are automatically transmitted via the cloud or data network 3 of system 1 to a target address of the laboratory information and management system 5-i of the respective laboratory measuring device operator LMGB and stored there in the associated laboratory database 6-i for further evaluation . In one possible embodiment, the conversion device 2 receives reports from the various laboratory measuring devices 4, which contain the laboratory device data from the laboratory measuring devices 4 in a structured form in an output data format. The conversion device 2 is able to read in and interpret various output data formats, in particular file formats. This laboratory device data contained within the received measuring device report is preferably automatically and standardized transferred to the LIMS via the API of the laboratory information and management system LIMS. The mapping engine 2A of the Konversionsvor direction 2 has, for example, a logic that the received laboratory device data in the data structure of the laboratory Information and Management System (LIMS) 5 of the laboratory measuring device operator LMGB.

In one possible embodiment, the mapping information or mapping configuration data contained in the mapping table MT of the laboratory measuring device operator LMGB are configured in a configuration routine. In a further possible embodiment, the laboratory measuring device 4 is automatically updated by the laboratory measuring device operator LMGB of the sen mapping table MT during operation. In a preferred embodiment of the system 1 according to the invention, the mapping of the data fields is bidirectional, i.e. in the directions. The laboratory device data stored in the laboratory database 6-i in the target data format of the laboratory information and management system (LIMS) 5 of the laboratory measuring device operator LMGB can be converted into the output data format of the laboratory measuring device 4 in accordance with the data stored in the mapping table MT of the laboratory measuring device operator LMGB Mapping information can be converted back. In one possible embodiment, this can take place in response to a reverse conversion control command. The conversion device 2 is able to process a large number of different output and target data formats. The data formats include in particular a CSV data format, a JSON data format and an XML data format. The CSV (Comma-Separated Values) file format describes the structure of a text file for storing or exchanging simply structured data that are separated from one another by commas, for example.

The use of an XML file allows the use of complex data structures. XML files can be used to save data and formatting together with raw values or raw data from the measurements. Thanks to the flexibility of the XML data format, additional information can be structured with the measurement data. can be saved. These XML files can be opened and edited in text editors and XML-enabled browsers. Tags are used to describe the file structures. While XML files require a relatively large amount of storage space, Technical Data Management Streaming TDMS files only take up a small amount of storage space because it is a binary data format. TDMS files have a file header in which descriptions or additional information can be saved together with the laboratory device data. In addition, the data formats can include an INI data format, an ODS data format, an ODT data format, an RSS data format, an RDF data format, a TXT data format and a JSON data format. These data formats are machine-readable. In one possible embodiment, a sample number of the material sample is recorded during a measurement with the laboratory measuring device 4. This is done, for example, by manually entering a sample number or via a barcode reader of the laboratory measuring device 4. During a measurement run, the measurement results can be collected and exported using control software of the laboratory measuring device 4 and saved in an export file in an output data format. The export file is transmitted in the output data format from the laboratory measuring device 4 to the conversion device 2 via a data interface. In one possible embodiment, the export file is transmitted to a configurable network address of the conversion device 2. After importing the transferred file, the conversion device 2 can automatically convert the output data format of the laboratory measuring device 4 into the target data format of the laboratory information and management system LIMS of the laboratory measuring device operator LMGB. For this purpose, the mapping table MT of the recognized or detected laboratory measurement device operator LMGB, which is stored in the configuration memory 2B, is used by the mapping engine 2A. The transmission of the laboratory measuring device data to the conversion device 2 takes place in a possible embodiment by wire. Alternatively, the laboratory measuring device data can also be transmitted wirelessly from a laboratory measuring device 4 to the conversion device 2. In one possible embodiment, the laboratory device data provided by the laboratory measuring device 4 are transmitted in the output data format as useful data in data packets. The data packets contain the laboratory device data as payload data. For the packet-wise transmission of the laboratory device data, the laboratory device data in an alternative embodiment can also be transmitted in a data stream from the laboratory measuring devices 4 to the conversion device 2 and from there in converted form to the laboratory information and management systems LIMS. In a preferred embodiment, there is a bidirectional communication connection between the laboratory measuring device 4 of the laboratory measuring device operator LMGB and the laboratory information and management system LIMS 5-i of the laboratory measuring device operator LMGB during operation of a laboratory measuring device 4 of a laboratory measuring device operator LMGB. The bidirectional communication connection can be established indirectly via the conversion device 2 or, alternatively, directly between the laboratory measuring device 4 and the LIMS of the laboratory measuring device operator LMGB. The bidirectional communication connection is used for protocol-independent communication and for the transmission of laboratory device data to the laboratory information and management system (LIMS) 5 of the laboratory measuring device operator LMGB and for the transmission of control commands CMD from the laboratory information and management system (LIMS) 5 of the Laboratory measuring device operator LMGB to its laboratory measuring devices 4. Fig. 1 shows schematically the transmission of control commands CMD (Commands) to the laboratory information and management system (LIMS) 5-i of the laboratory measuring device operator LMGB via the data network or the cloud 3 to the conversion device 2 and from there to the respective laboratory measuring devices 4-i of the laboratory measuring device operator LMGB _j. . In one possible embodiment, the exchange of laboratory device data and the control commands CMD takes place in real time via the bidirectional communication connection existing between the laboratory information and management system (LIMS) 5 and the laboratory measuring device 4. In this embodiment, the laboratory information and management system (LIMS) 5 of the laboratory measuring device operator LMGB has real-time data and can thus influence the measurement during a measuring process carried out by the laboratory measuring device 4. In order to be able to influence the real-time measuring process, the laboratory information and management system (LIMS) 5 of the laboratory measuring device operator LMGB can send corresponding control commands or commands CMD to the conversion device 2 and / or to the laboratory measuring device 4-i of the laboratory measuring device operator Submit LMGB. These control commands CMD can contain, for example, measurement specifications for carrying out a measurement on a material sample. For example, target values or limit values for performing a material sample measurement can be transmitted to the laboratory measuring device 4. These measurement specifications can be adapted dynamically during the measurement process with the aid of the transmitted measurement control commands CMD. The measurement specifications are usually device-dependent. For example, the amount of purging gas differs from DSC devices from different manufacturers. The amount of material required for a material sample also depends on the device type and / or device manufacturer. The control commands CMD can also include conversion control commands. For example, the laboratory information and management system (LIMS) 5-i can control the target data format in which it wants to receive the laboratory measuring device data from the laboratory measuring device 4 or which target is pursued with a measurement becomes. The control commands CMD of the laboratory information and management system (LIMS) 5, which are received by the conversion device 2, can also change the content of the mapping table MT, which is stored in the configuration data memory 2B of the conversion device 2, and thus the mapping between affect the data fields. There is thus also the possibility that the laboratory information and management system (LIMS) 5 of the laboratory measuring device operator LMGB updates the mapping table MT of the laboratory measuring device operator LMGB during ongoing operation of the laboratory measuring devices. With the aid of the system 1 according to the invention, as shown in FIG. 1, the exchange or replacement of a laboratory measuring device 4 by another laboratory measuring device 4 is simplified. There is also the possibility of automatically updating inventory data of a laboratory measuring device 4. When a first laboratory measuring device 4 is replaced by a second laboratory measuring device 4 ', the laboratory device data of the first original, stored in the laboratory database 6-i of the laboratory information and management system (LIMS) 5-i of the laboratory measuring device operator LMGB, are preferably stored in the target data format Laboratory measuring device 4 automatically updated seamlessly with laboratory device data of the second new laboratory measuring device 4 in the target data format. This gives the laboratory measuring device operator LMGB the possibility of replacing an old laboratory measuring device 4 from a certain laboratory measuring device manufacturer and / or a certain laboratory measuring device type with a second new laboratory measuring device 4 'from another laboratory measuring device manufacturer and / or another laboratory measuring device type without losing access to inventory data . The laboratory information and management system (LIMS) 5 of the laboratory measuring device operator LMGB can, in one possible embodiment, determine the respective utilization of the various laboratory measuring devices 4 of the laboratory measuring device operator LMGB using the Determine or determine laboratory device data that is present in the target data format of the laboratory information and management system LIMS and that is converted into the laboratory database 6-i of the laboratory information and management system 5- i. On the basis of the determined individual workloads (e.g. number of material samples per period) of the various laboratory measuring devices 4-i of the laboratory measuring device operator LMGB, the laboratory information and management system 5-i of the laboratory measuring device operator LMGB can then increase the total capacity of the laboratory measuring devices 4-i of the laboratory measuring device operator LMGB, by transmitting corresponding control commands CMD to the laboratory measuring devices 4-i of the laboratory measuring device operator LMGB. The laboratory measuring devices 4-i of the laboratory measuring device operator LMGB include, in particular, material testing measuring devices for performing measurements on material samples P which are heated, for example, in a heating furnace 4A of a laboratory measuring device 4. The measurement data generated by the sensors are transmitted in a defined output data format via the data interface of the laboratory measuring device 4-i to the conversion device 2, where they are automatically converted into the target data format of the laboratory information and management system 5-i of the laboratory measuring device operator LMGB . In one possible embodiment, each laboratory measuring device 4-i can measure one or more material samples P at the same time. If the laboratory information and management system 5-i of the laboratory measuring device operator LMGB recognizes on the basis of the measurement data available in the target data format, that a laboratory measuring device 4-i of a laboratory measuring device operator LMGB is fully utilized, while another laboratory measuring device 4-i of the same laboratory measuring device operator LMGB is still th has free capacities, material samples P can be automatically diverted to the not yet fully utilized laboratory measuring device, so that the total utilization of the laboratory measuring devices 4-i des Laboratory measuring device operator LMGB is automatically increased. The redistribution or redirection of material samples P can also take place in real time with the aid of control commands CMD for laboratory measuring devices 4 that are not yet fully utilized. In one possible embodiment, the conversion device 2 shown in FIG. 3 offers a virtualization layer. Here, the conversion device 2 creates a virtual group of laboratory measuring devices of the same type for capacity and order planning by the laboratory information and management system LIMS of the laboratory measuring device operator LMGB from a connected group of laboratory measuring devices 4-i of a laboratory measuring device operator LMGB.

In one possible embodiment of the system 1 according to the invention, a universal, standardized target data format is provided which enables laboratory device data from laboratory measuring devices 4-i of different laboratory measuring device drivers LMGB to be compared. In one possible embodiment, the conversion device 2 converts the received laboratory device data from a laboratory measuring device 4-i of a laboratory measuring device operator LMGB not only into the specified target data format of the laboratory information and management system (LIMS) 5-i of the laboratory measuring device operator LMGBi concerned, but also into Another universal target data format of the system 1, which is preferably supported by all integrated laboratory information and management systems 5-i of the various laboratory measuring device operators LMGBi. The laboratory device data stored in the uniform or comparison target data format in the laboratory databases 6-i of the various laboratory information and management systems 5-i allow different laboratory measuring devices 4-i to be determined with regard to their performance and / or to compare measurement accuracy. For example, a material sample P can be divided and measured in parallel by two laboratory measuring devices 4-i of the same type, but from different manufacturers, and the laboratory measuring device data thus produced are automatically compared with one another by an analysis / computing unit of system 1. This allows, for example, the automatic calibration of a laboratory measuring device 4 by means of a reference laboratory measuring device.

Fig. 2 shows a flow chart of a possible embodiment of the computer-implemented method according to the invention for efficient operation of laboratory measuring devices 4 of an LMGB, in particular to increase the utilization of laboratory measuring devices 4 of the laboratory measuring device operator LMGB.

In the flowchart shown in FIG. 2, the computer-implemented method essentially comprises three main steps S1, S2, S3.

In a first step S1, laboratory device data are received from a laboratory measuring device 4-i of the laboratory measuring device operator LMGB in an output data format.

In a further step S2, the laboratory device data received are automatically converted into a target data format of the laboratory information and management system (LIMS) 5 of the laboratory measuring device operator LMGB. In doing so, data fields of the output data format are automatically mapped or converted to data fields of the target data format in accordance with mapping information stored in the mapping table MT of the laboratory measuring device operator LMGB. In a further step S3, the converted laboratory device data are written in the target data format into a laboratory database 6 of the laboratory information and management system (LIMS) 5 of the laboratory measuring device operator LMGB, the laboratory measuring devices of the laboratory measuring device operator (LMGB) with the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) to increase the overall utilization of the laboratory measuring devices (4) of the laboratory measuring device operator (LMGB).

The computer-implemented method can be implemented as middleware.

In an optional step S4, the utilization of the laboratory measuring devices 4-i can be determined or ascertained using the laboratory device data available in the target data format of the laboratory information and management system LIMS of the laboratory measuring device operator LMGB. The utilization of a laboratory measuring device 4 can include the number or the amount of material samples P measured by a laboratory measuring device 4 per time period.

In one possible embodiment, the laboratory measuring devices 4-i can be controlled by the laboratory information and management system (LIMS) 5 of the laboratory measuring device operator to increase the overall utilization of the laboratory measuring devices 4-i of the laboratory measuring device operator LMGB in an optional step S5. For this purpose, the laboratory information and management system (LIMS) 5 of the laboratory measuring device operator LMGB outputs control commands CMD, which are transmitted to the laboratory measuring devices 4-i of the laboratory measuring device operator LMGB directly via the cloud 3 and / or indirectly via the conversion device 2. The total utilization gives the total amount or total number of all material samples P measured by the laboratory measuring devices 4 of the laboratory measuring device operator LMGB per time period (for example per day).

FIG. 4 shows, by way of example, the mapping of laboratory device data in the method according to the invention. In the example shown, a laboratory measuring _{device LMG X} outputs laboratory device data in a structured form in an output data format. In the example shown, the output data format comprises seven different data fields for different laboratory device data. In the example shown, the laboratory device data comprise, on the one hand, measurement data and, on the other hand, master data of the laboratory measuring device. In the example shown, the output data format of the laboratory measuring device 4 comprises various data fields, namely a first data field for temperature measurement data T, a second data field for the measurement duration At, a third data field for the material M of the material sample, a fourth data field for the mass m the material sample P, a fifth data field for the date D of the measuring process, a sixth data field for a time t of the measuring process and a seventh data field LMG-ID for identifying the laboratory measuring device. In the example shown in FIG. 4, the laboratory _{measuring device LMG X is operated} by a laboratory measuring device operator LMGB who uses the laboratory information and management system LIMS _Ä . This laboratory information and management system LIMS _A uses a data structure with seven data fields as the target data format. The target data format comprises a first data field for the mass m of the material sample, a second data field for the device ID (LMG ID) of the laboratory measuring device, a third data field for the time t of the measurement, a fourth data field for the date D of the Measurement, a fifth data field for the temperature T of the measurement, a sixth data field for the duration At of the measurement and a seventh data field M for the material of the material sample. According to the mapping information which is stored in the mapping table MT of the laboratory measuring device operator LMGB of the laboratory measuring device LMG _X , the data contained in the various data fields are mapped, as shown schematically in FIG. For example, the temperature measurement data T located in the first data field of the output data format are mapped to the fifth data field of the target data format of the laboratory information and management system LIMS _Ä . The data stored in the second data field of the output data format, which indicate the duration At of the measurement process carried out, are mapped into the sixth data field of the target data format, etc. in the example shown Information or data stored in data fields is carried out bidirectionally in a preferred embodiment, as shown in FIG. The mapping relates to the assignment as shown in FIG. 4. The conversion or Umkonvertie ren relates to a change in the data format or the language or syntax with which the measurement data are made available by the device. Mapping and converting can be carried out independently of one another. Alternatively, mapping and conversion can also be carried out simultaneously in one step.

As shown in FIG. 5, each laboratory measuring device LMG _X , LMG _y , LMG _{Z can} transmit comparable measurement parameters or information in different data fields of an output data format. For example, the temperature data T in the first laboratory measuring device LMG _X in the first data field, in the second laboratory measuring device LMG _y in the ninth data field and in the third laboratory measuring device LMG _Z in the third data field of the output data format. In the same way, measurement parameters or master data information can be chen data fields of a target data format of a laboratory information and management system LIMS are transmitted or stored. For example, the material information M in the example shown in FIG. 5 in the first laboratory information and management system LIMS _A in the seventh data field of the target data format, in the second laboratory information and management system LIMS _B in the first data field Target data format and in the third laboratory information and management system LIMS _C in the fifth data field of the target data format. The number of data fields in the source and target data formats can vary depending on the application. Not all data fields of a data format have to be filled.

For example, in the example shown in FIG. 5, the laboratory _{measuring device LMG X is used} by a Labormessgerätebe driver LMGB who has the laboratory information and management system LIMS _Ä , which is contained in the first data field of the output data format of the laboratory measuring device _{LMG X.} tene temperature information T in the fifth data field of the output data format of the laboratory information and management system LIMS _A mapped or copied. If, on the other hand, the same laboratory measuring device LMG _X is used by another laboratory measuring device operator LMGB who has the second laboratory information and management system LIMS ₀ , the temperature data T contained in the first data field of the output data format are transferred to the eighth data field of the target - Data formats of the second laboratory information and management system LIMS _B mapped or copied. The system 1 according to the invention is therefore suitable for any laboratory measuring devices LMG and different laboratory information and management systems LIMS. By adapting the mapping table MT accordingly, there is also the possibility in the system 1 according to the invention possibility that a laboratory measuring device operator LMGB can switch seamlessly between different laboratory information and management systems LIMS.

Fig. 6 shows a possible application example of the fiction, contemporary system 1 for the efficient operation of Labormessge devices 4, in particular to increase the utilization of laboratory measuring devices 4. In the application example shown in Fig. 6, the laboratory measuring device 4 of the system 1 is connected to a production plant 7 coupled with different production stages 8. In the production stage 8, a material _{sample P j} is removed manually or automatically and placed in a heating furnace 4A of the laboratory measuring device 4. The laboratory measuring device 4 has several sensors 4B-1, 4B-2, 4B-n for different measurement parameters, for example measurement temperature T, material mass or material expansion. These measurement data or sensor data are written by a processor or controller 4C of the laboratory measuring device 4 into an output file which is output to the conversion device 2 via a data interface 4D of the laboratory measuring device 4 via the cloud or the data network 3. The output or export file has an output file format. The controller 4C can carry out a measurement sequence control and, for example, control a heating element 4E of the laboratory measuring device 4. A user of the laboratory measuring device 4 can use a user interface 4F to set parameters of the measuring process or to make input commands. Furthermore, measurement data can be displayed to the user via the graphical user interface 4F of the laboratory measuring device 4. The measurement data present in the output data format can additionally be stored or temporarily stored in a local data memory 4G of the laboratory measuring device 4. The controller 4C of the laboratory measuring device 4 can via a further data interface 4H with a system control 9 of the production system 7 verbun to be. In one possible embodiment, this system control 9 generates control signals CRTL for various production stages 8 of the production system 7 as a function of the laboratory device data present in the output data format, as shown schematically in FIG. If, for example, the laboratory device data of the laboratory measuring device 4 indicates that the material sample P located in the heating furnace 4A, which was _{taken from the production stage 8 j} , does not offer sufficient quality, the system control 9 can control the upstream production stages of the production system 7 in order to restore sufficient quality To produce quality. In the illustrated embodiment, an analysis unit of the system control 9 evaluates the laboratory device data provided by the laboratory measuring device 4 in the output data format and controls one or more production stages 8 of the production system 7 as a function of the analysis result. In a further possible embodiment, the laboratory information and management system LIMS of the laboratory measuring device operator LMGB of the laboratory measuring device 4 can generate control commands or commands CMD, which are transmitted via the laboratory measuring device 4 to the plant control 9 of the production plant 7 in order to control the production plant 7 accordingly head for. In an alternative embodiment, the laboratory information and management system LIMS 5 of the laboratory measuring device operator LMGB can control the system control 9 of the production system 7 directly. For this purpose, the system control 9 is connected to the data network or the cloud 3 of the system 1 via an interface. In one possible embodiment, the data exchange for the transmission of the control commands CMD takes place in real time during the production process. The network infrastructure 3 of the system 1 according to the invention can use different network protocols, in particular TCP / IP. Via the network information rastructure 3 of the system 1, the laboratory measuring devices 4 can be connected as clients to a server which executes a server application. In one possible embodiment, this server application can carry out one or more main steps of the computer-implemented method shown in FIG. 2. The server application can also be distributed over several servers, which can be operated internally or externally by IT service providers or in the cloud. In a further possible embodiment, the laboratory measuring device 4 shown in FIG. 6 has a further data interface for connecting a local computer or PC. This PC preferably offers the user of the LIMS application a graphical user interface. The LIMS application can be partially or completely operated via a web browser. The LIMS application can partly also be provided using mobile devices or tablets. The system 1 according to the invention has a manufacturer-independent networking of different types of laboratory measuring devices 4 from different laboratory measuring device operators LMGB to different laboratory information and management systems LIMS. Manual data storage is avoided and capacity planning for the various laboratory measuring devices 4 is made easier. The system 1 according to the invention also enables benchmarking of the performance or capability of various laboratory measuring devices 4. Using the system 1 according to the invention, laboratory measuring devices 4 of different types or different manufacturers can be easily exchanged by the laboratory measuring device operator LMGB without access to existing inventory data or Losing measurement data or without the need to manually adjust this inventory data. The system 1 according to the invention is also real-time capable, ie the capacity planning or the load adjustment can take place in real time. The convert Approximation device 2 preferably offers a bidirectional interface between the laboratory measuring devices 4 on the one hand and the laboratory information and management systems (LIMS) 5 on the other hand. The Laboratory Information and Management System (LIMS) 5 offers the user a wide range of functions, in particular for recording measurement data, support with sample distribution and processing, order registration and sample registration, release of test results as well as measurement data evaluation and calculation of analysis results.

In a preferred embodiment, the configuration device 2 can be installed on a server of a cloud platform. This offers greater reliability and availability thanks to a redundant server system. Furthermore, the laboratory database 6 of the laboratory information and management system (LIMS) 5 can be accessed from anywhere. The data backup can take place at a high frequency, for example in seconds. With the help of the server system of the cloud platform, a high level of performance can be achieved when evaluating and managing the laboratory device data. In one possible embodiment, the laboratory database 6 of the laboratory information and management system 5 is constructed in such a way that all components are redundantly distributed in various independent availability zones. This reduces the probability of the laboratory database 6 of the laboratory information and management system 5 failing.

Further embodiments of the system 1 according to the invention are possible. For example, in one possible embodiment, the laboratory device data is transmitted in encrypted form. The laboratory device data can also be coded in one possible variant in order to reduce transmission errors.

Claims

PATENT CLAIMS

1. Computer-implemented method for the efficient operation of laboratory measuring devices (4) from a laboratory measuring device operator (LMGB) with the following steps:

- Receiving (Sl) of laboratory device data which are output by different types of laboratory measuring devices (4) of the laboratory measuring device operator (LMGB) in different output data formats;

- Conversion (S2) of the received laboratory device data into at least one specified target data format of a laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB), with data fields of the output data formats correspondingly stored for the laboratory measuring device operator (LMGB) Mapping information is automatically converted to data fields of the target data format;

- Writing (S3) the converted laboratory device data in the target data format into a laboratory database (6) of the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB), the laboratory measuring devices of the laboratory measuring device operator (LMGB) with the laboratory - Communicate information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) to increase the overall utilization of the laboratory measuring devices (4) of the laboratory measuring device operator (LMGB).

2. Computer-implemented method according to claim 1, wherein the respective utilization of a laboratory measuring device (4) of the laboratory measuring device operator (LMGB) by the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) based on the in the target data format of the Laboratory information and management systems, LIMS, (5) of the laboratory measuring device operator (LMGB) converted and ascertained in the laboratory database (6) of the laboratory information and management system, LIMS, (5) registered laboratory device data (S4).

3. Computer-implemented method according to claim 2, wherein the laboratory measuring devices (4) of the laboratory measuring device operator (LMGB) by the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) depending on the determined utilization of the laboratory measuring device (4 ) to control the total utilization of the laboratory measuring devices of the laboratory measuring device operator (LMGB) can be controlled (S5).

4. Computer-implemented method according to one of claims 1 to 3, wherein the laboratory device data of the laboratory measuring device (4) include master data of the laboratory measuring device (4), measurement data of the laboratory measuring device (4) and / or status data of the laboratory measuring device (4).

5. Computer-implemented method according to one of claims 1 to 4, wherein the different types of laboratory measuring devices (4) of the laboratory measuring device operator (LMGB) include laboratory measuring devices (4) from different laboratory measuring device manufacturers and / or different types of laboratory measuring devices, the master data the laboratory measuring device (4) as well as generating measurement data and outputting them in a defined output data format of the laboratory measuring device (4).

6. Computer-implemented method according to one of the preceding claims 1 to 5, wherein the output data formats of the laboratory measuring devices (4) contain structured data sets with data fields for different measurement parameters and / or master data types.

7. Computer-implemented method according to one of the preceding claims 1 to 6, wherein the mapping information of the laboratory measuring device operator (LMGB) is stored in a configurable mapping table (MT), which is a data field of the target data format of the laboratory information for each data field of an output data format and management system, LIMS, (5) of the laboratory measuring device operator (LMGB).

8. Computer-implemented method according to one of the preceding claims 1 to 7, wherein during the conversion process for converting the received laboratory device data into at least one predetermined target data format of the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) the laboratory device data contained within a data field of the output data format are imported into the assigned data field of the target data format of the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB).

9. Computer-implemented method according to claim 7 or 8, wherein the mapping information contained in the mapping table (MT) of the laboratory measuring device operator (LMGB) is configured in a configuration routine and / or automatically updated during the operation of the laboratory measuring device (4) of the laboratory measuring device operator (LMGB).

10. Computer-implemented method according to one of the preceding claims 1 to 9, wherein the laboratory device data of the laboratory measuring device stored in the target data format of the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) in the laboratory database (6) 4) in response to a conversion control command to be converted back into the output data format of the laboratory measuring device (4) according to the mapping information stored in the mapping table (MT) of the laboratory measuring device operator (LMGB).

11. Computer-implemented method according to one of the preceding claims 1 to 10, wherein the laboratory measuring device (4) of the laboratory measuring device operator (LMGB) has a material testing measuring device for performing measurements on material samples (P), with measurement data generated by a measurement in an output data format can be output via a data interface of the laboratory measuring device (4).

12. Computer-implemented method according to claim 11, wherein a controller (4C) of the laboratory measuring device (4) of the laboratory measuring device operator (LMGB) during operation of the laboratory measuring device (4) by the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) Receives measurement control commands with measurement specifications for performing measurements on material samples (P).

13. Computer-implemented method according to one of the preceding claims 1 to 12, wherein the laboratory measuring device (4) of the laboratory measuring device operator (LMGB) as a client provides laboratory device data in an output data format of the laboratory measuring device (4), which is provided as useful data in data packets via a data network

(3) are transmitted to a conversion device (2) implemented on a local or remote server, the server executing a server application which automatically stores the laboratory device data received from the laboratory measuring device (4) in accordance with the data stored for the laboratory measuring device operator (LMGB) Mapping information converted into the specified target data format of the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB).

14. Computer-implemented method according to one of the preceding claims 1 to 13, wherein when a first laboratory measuring device is exchanged

(4) a specific laboratory measuring device manufacturer (LMGB) and / or a specific laboratory measuring device type by another second laboratory measuring device (4 ') from another laboratory measuring device manufacturer (LMGB') and / or another laboratory measuring device type in the laboratory database (6) of the laboratory information - and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) in the target data format stored laboratory device data of the first laboratory measuring device (4) are automatically updated seamlessly with laboratory device data of the second laboratory measuring device (4 ') in the target data format.

15. Computer-implemented method according to one of the preceding claims 1 to 14, wherein during the operation of a laboratory measuring device (4) of a laboratory measuring device operator (LMGB) between the laboratory measuring device (4) of the laboratory measuring device operator (LMGB) and the laboratory information and management system, LIMS , (5) of the laboratory measuring device operator (LMGB) there is a bidirectional communication link for the exchange of laboratory device data and control commands.

16. Computer-implemented method according to claim 15, wherein the exchange of the laboratory device data and the control commands via the bidirectional communication link between the laboratory measuring device (4) and the laboratory information and management system, LIMS, (5) takes place in real time.

17. System (1) for the efficient operation of laboratory measuring devices (4) of a laboratory measuring device operator (LMGB), the system (1) having:

- Laboratory measuring devices (4) of the laboratory measuring device operator

(LMGB), each of which provides laboratory device data in different output data formats; a conversion device (2) for converting the received laboratory device data into at least one specified target data format of a laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB), with data fields of the output data formats corresponding to the laboratory measuring device operator (LMGB) stored cherter mapping information is automatically converted to data fields of the target data format;

- a laboratory database (6) of the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB), in which the data format of the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) converted laboratory device data are written; whereby the laboratory measuring devices of the laboratory measuring device operator (LMGB) communicate with the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) to increase the overall utilization of the laboratory measuring devices (4) of the laboratory measuring device operator (LMGB).

18. System according to claim 17, wherein the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) the respective utilization of the laboratory measuring devices (4) of the laboratory measuring device operator (LMGB) based on the in the target data format of the laboratory Information and management system, LIMS, (5) converted and recorded in the laboratory database (6) of the laboratory information and management system, LIMS, (5) ascertained laboratory device data and the laboratory measuring devices (4) of the laboratory measuring device operator (LMGB) to increase the total utilization of the laboratory measuring devices (4) of the laboratory measuring device operator (LMGB) by means of control commands (CMD) which the laboratory information and management system, LIMS, (5) of the laboratory measuring device operator (LMGB) controls to the laboratory measuring devices (4) of the laboratory measuring device operator (LMGB) ) transmits.

19. Conversion device (2) for the automatic conversion of laboratory device data received in different output data formats into at least one specified target data format of a laboratory information and management system, LIMS, (5) of a laboratory measuring device operator (LMGB), with data fields being the output -Data formats are automatically mapped to data fields of the target data format in accordance with the mapping information stored in a mapping table (MT) of the laboratory measuring device operator (LMGB).