DE102017127310A1 - Optical topology determination in measuring device - Google Patents

Abstract

Device (100) for determining indicia information for a topology of a measuring device, in particular a sample separating device (10), having a plurality of modules (102) and the modules (102) fluidly coupling fluid lines (104), the device (100) having a Image data evaluation device (106) for evaluating at least part of the measuring device, in particular a sample separation device (10), image data and imaging means (108) for determining the information indicative of the topology based on the evaluated image data.

Description

TECHNICAL BACKGROUND

 The present invention relates to a device, an arrangement and a method for determining information indicative of a topology of a measuring device (in particular a sample separating device), and to a measuring device (in particular a sample separating device). Moreover, the present invention relates to a computer-readable storage medium and a program element.

In an HPLC, a liquid (mobile phase) is typically run at a very precisely controlled flow rate (for example in the range of microliters to milliliters per minute) and at a high pressure (typically 20 to 1000 bar and beyond, currently up to 2000 bar). , in which the compressibility of the liquid is felt, by a so-called stationary phase (for example in a chromatographic column), moved to separate individual components of a sample liquid introduced into the mobile phase from each other. Such an HPLC system is for example from EP 0,309,596 B1 by the same Applicant, Agilent Technologies, Inc.

 To control such an HPLC system, knowledge of the topology of fluid coupling of the constituents of the HPLC system is desirable.

EPIPHANY

 It is an object of the invention to determine the topology of the fluidic coupling of the constituents of a measuring instrument with little error or, if appropriate, even without errors and simply. The object is achieved by means of the independent claims. Further embodiments are shown in the dependent claims.

 According to an exemplary embodiment of the present invention, a device for determining fluid lines (in which a fluid is coupled) of a measuring device (in particular a sample separation device) having a plurality of modules and the modules is fluidically coupled (wherein a fluid is a gas and / or a fluid Liquid, optionally containing solid particles) indicative information (also referred to as topology information) created, the device based Bilddatenauswerteinrichtung for evaluating at least a part of the measuring device (in particular of the sample separation device) image-forming image data and a determination device for determining the information indicative of the topology information on the evaluated image data.

 According to another exemplary embodiment, a measuring device (in particular a sample separating device for separating a fluidic sample) is provided, wherein the measuring device (in particular the sample separating device) comprises a plurality of modules for providing a respective function during the measuring (in particular in the context of separating the fluidic sample ), Fluid conduits by means of which the modules are fluidically coupled, a device with the features described above for determining information indicative of a topology of the fluidic coupling of the modules by means of the fluid conduits and a control device for controlling the modules for measuring (in particular for separating the fluidic Sample) using information indicative of the topology.

 According to another exemplary embodiment, there is provided an arrangement comprising a measuring device (in particular a sample separation device) having the features described above and a portable user device adapted to receive at least a portion of the image data and transmit the captured image data to the device.

 According to another exemplary embodiment, a method is provided for determining fluidic lines of indicative information that are fluidically coupled to a topology (in particular a fluidic coupling) of a measuring device (in particular a sample separating device) having a plurality of modules and the modules, wherein in the method at least a part of the Measuring device (in particular of the sample separation device) imaging image data are evaluated and the information indicative of the topology based on the evaluated image data is determined.

 A computer-readable storage medium according to an embodiment of the present invention stores a program for determining a fluidic topology of a meter, which program, when executed by one or more processors, controls the method steps described above.

 A program element (in particular a computer program element) according to an exemplary embodiment of the present invention for determining a fluidic topology of a measuring device has (or performs) the method steps described above if it is carried out by one or more processors.

Embodiments of the present invention can be implemented either by means of a computer program, that is to say a software, or by means of one or more special electrical circuits, that is to say in hardware, or in any desired way hybrid form, that is to be realized by means of software components and hardware components. In particular, in one embodiment of the invention, the software may be at least partially designed as an app, ie as a downloadable and then installable software application for the device and / or the portable user device.

 In the context of the present application, the term "measuring device" is understood in particular to mean a device which qualitatively and / or quantitatively measures at least one parameter to be measured and / or at least one event to be measured, using one or more fluids. In this case, the fluid can be the object and / or aid of the measurement. An example of such a measuring device is a sample separation device (in particular a chromatography device), with which a fluidic sample is separated into its fractions and these are optionally identified or quantified.

 In the context of the present application, the term "module" or "fluidic node" is understood in particular to mean a fluid component which has at least one fluidic port and can be designed to provide a fluid processing function for processing fluid flowing through the measuring device. Examples of these are modules of a chromatographic apparatus, for example a degasser, a fluid drive (for example a high-pressure chromatography pump), a sample injector, a sample separator (for example a chromatography separation column), a detector (for example a fluorescence detector) or a fractionator. A port of a fluidic node or module may be fixedly or detachably coupled to a fluidic port of a fluid conduit or fluidic connector.

 In the context of the present application, the term "fluid line" or "fluidic connection element" is understood to mean, in particular, a line section designed to carry a fluid, which can have at least two fluidic connections and can be designed to pass fluid flowing through the measuring device. Examples of a fluidic connection element are branched or unbranched capillaries, hose connections, cavities in a laminate component (ie a fluidic component formed from interconnected layers with recesses therein), etc. A connection of a fluid conduit can be fixed or detachable to a port of a module or fluidic Knotens be coupled.

 In the context of the present application, the term "topology of a fluidic coupling" is understood to mean, in particular, the structure of a fluidic space or network which indicates or maps the fluidic coupling between fluidic modules (and optionally also the fluid conduits). In particular, for a portion or each of the modules, the topology may indicate to which fluid lines that module is directly fluidly connected. Further, the topology may include the identity (which may be determined, for example, by a unique identifier, for example in the form of an alphanumeric code, a part number, etc.) of a particular module, particularly the particular port of a module, and / or a particular fluid conduit, in particular their port / connection. In one embodiment, the topology includes information as to which ports of fluidic modules are directly fluidly coupled to which ports of fluid conduits, and which properties the implemented fluidic modules as well as the implemented fluid conduits have.

 In the context of the present application, the term "topology information" is understood to mean, in particular, a data record which allows conclusions to be drawn, deriving or ascertaining the topology of the fluidic system from modules and fluid lines, i. which modules are fluidically connected to which other modules via which fluid lines. Topology information can be optically acquired (for example in the form of detection data) and evaluated or processed into a topology image.

According to an exemplary embodiment, the topology of a fluidic coupling between modules of a measuring device (preferably a sample separation device) using fluid lines can be clarified by taking one or more images of parts of the measuring device or of the entire measuring device and evaluating these images in order to obtain the images Identify fluid lines and the modules and / or identify their coupling. In this way it is possible, for example, with little effort, that a control device of the measuring device is informed about the fluidic coupling of the modules and the fluid lines of the measuring device, so that a control of the operation of the measuring device can be adjusted accordingly. The image data can be recorded, for example, by means of an image recording device provided therefor of the measuring device or the device for determining the topology information and / or by means of a camera of a portable user device. If the image recording device forms part of the measuring device, the measuring device together with the device can automatically accomplish the elucidation of the topology. Optical determination of the fluidic topology of a measuring device on the basis of image processing can be carried out fault-robustly, quickly and easily. The recorded image data can be easily obtained by means of automatic methods Object detection or the like are analyzed and thereby the individual fluid lines and modules spatially detected and possibly even identified in terms of their type. The optical clarification of the topology is fault-robust and user-friendly.

 According to an embodiment of the invention, when the meter is used in an assembly in combination with a user-managed portable user device (eg, a smartphone with a camera function), the user may communicate with the communicably coupled portable user device one or more images of the meter or of the device Include areas of it, on the basis of which the device can then enlighten the topology. The latter has the advantage that the device can instruct the user which information about the topology is still missing and which image data are therefore still needed. A user may very flexibly arrange a portable user device to desired locations and orientations to provide the requested or provided image data of particular details of the meter. In this way, a user can assemble the modules by means of fluid lines in almost any combination and configuration, and the meter can automatically or at least controlling the set topology enlighten. This is a very convenient way for a user to modularly assemble a meter and quickly begin its operation.

 Hereinafter, additional embodiments of the device, the measuring device (in particular of the sample separation device), the arrangement, the method, the computer-readable storage medium and the program element will be described.

 In one embodiment, the device may include a communication device for communicable coupling with a portable user device. The communication device can be used, for example, to receive image data recorded by the portable user device and to image the measuring device (in particular the sample separation device). According to such an embodiment, the portable user device may also comprise a communication device for communicable coupling with the device, in particular for transmitting image data and / or communication messages. The device can thus have a communication device which can communicate with a communication device of the portable user device unidirectionally or bidirectionally. This communication can be wired or wireless. For example, if the portable user device is a smartphone, communication may be via a telecommunications network or the Internet. In this way, the image data which the portable user device with an image recording device integrated therein has received from the measuring device (in particular the sample separation device) or parts thereof can be transmitted via the communication devices. In this way, already existing cameras can be used in portable user devices in many cases in order to provide the measuring device (in particular the sample separation device) with the necessary image data for elucidating the topology. In this case, it is advantageously possible to profit from the high flexibility of the operation of a portable user device, since the user can arrange this flexibly in certain spatial areas of the measuring device (in particular of the sample separating device) or selectively image specific sections thereof. This represents a particularly flexible solution.

 According to one exemplary embodiment, the communication device of the device can be set up to transmit an image data request message to the portable user device with which in particular additional and / or specifically defined image data representing the measuring device (in particular the sample separation device) are requested. According to such an embodiment, the portable user device may specifically provide the requested image data to the meter. According to such a preferred embodiment, the device can determine whether the image data already available to it via the measuring device (or its modules and fluid lines) is sufficient for determining the fluidic topology or whether further image data are required. For example, in the absence of certain image data, the device may specifically request the portable user device to pick up and transmit specially identified or described additional images of the meter or a portion thereof. Interactive user communication therefore enables the topology to be determined with high precision, quickly and efficiently.

According to one embodiment, the communication device of the device may be configured to specifically request from the portable user device such additional image data needed to close a gap in the already partially determined information indicative of the topology. Requested image data may be displayed, for example, on a display device (for example, an LCD display) of the portable user device and / or output via a voice output by means of a loudspeaker of the portable user device (for example: "Please take a picture of the bottom module of the tower , which shows its fluid connection to fluid lines! "or" Please create Take a picture of the barcode of the tower's top module! "). Gaps in the determined topology may be that certain fluidic couplings between certain modules and certain fluid lines could not yet be identified on the basis of the previously available image data. Gaps can also be that the identity of individual modules or the identity of individual fluid lines could not yet be determined. In the manner described, knowledge of the topology may be more specifically refined by requiring the user to provide additional image data specifically requesting such information that is still missing. The effort to determine the topology can be kept very low, as redundancies can be avoided.

 According to one exemplary embodiment, the device may be configured to transmit indicative information to the portable user device via the communication devices for operating the measuring device (in particular the sample separating device). The communication between the device and the portable user device can thus also take place in such a way that the device instructs the portable user device or provides it with information concerning the operation of the measuring device. Both can be done, for example, via a display device of the portable user device and / or via a voice output by means of a loudspeaker of the portable user device. For example, during device setup by a user, the device may assist the user via the portable user device, indicate faults or possible alternatives, or provide specific guidance as to which modules should be coupled to which fluid lines in which way. In this preferably bidirectional communication, the device and the user can enter into dialogue via the portable user device, so that there is no hierarchy between the device and the user (in the sense of a commanding controller and a command executing receiver or a master and a slave), but the reciprocal needs of the device for the elucidation of the topology and the user to support the construction or operation of the meter can be taken into account. Specifically, through the communication between the device and the portable user device, the user may be assisted during setup (eg, first mounting a sample separator) via communication messages of the device to the portable user device. In other words, an interactive user manual may be provided that guides the user through the installation. It is also possible for the user to be given information about the modules used and / or the fluid lines used by this communication on the portable user device. If the device determines that a user's configuration could lead to errors or problems in operation in the meter's modular assembly, an alternate mode of operation may be suggested to the user. The user may also be suggested an alternative composition of the modules or the fluid lines.

 According to one exemplary embodiment, the information indicative of the operating mode of the measuring device (in particular of the sample separating device) can therefore be selected from a group consisting of information for supporting a mounting of the measuring device (in particular of the sample separating device), information on individual modules and / or fluid lines, proposals to redesign the topology and operational information. The user can also be informed of the operation by means of the portable user device during operation of the measuring device (in particular of the sample separating device). Adjustments to operating parameters can then be triggered by the user via this communication.

In one embodiment, the device may be configured to communicate with the portable user device via augmented reality. Under Augmented Reality (or augmented reality) can be understood in particular the computer-aided extension of the perception of reality by providing additional information. This information can appeal to all human sensory modalities. In particular, augmented reality can be understood as the visual representation of information, that is to say the supplementation of images or videos with computer-generated additional information or virtual objects by means of superimposition or superimposition. By integrating elements of augmented reality into the communication between the portable user device and the device, the user can be even more intuitively instructed to provide, for example, desired image data. For example, when a user holds his portable user device in a manner that does not allow the desired image data to be captured, the user can be guided by arrows on the display device of the portable user device to adjust the desired position or orientation of the portable user device to obtain the desired image data to be able to record. If an actual orientation then coincides with a desired orientation, this can be indicated, for example, by a green frame or another optical signal on the display. It is also possible to direct the camera of a portable user device, for example, on one of the modules or one of the fluid lines and on the display additional information about this module or this fluid line (for example, the type of chromatographic separation column contained in a module).

 According to one exemplary embodiment, the device may have at least one image recording device for recording at least part of the image data for transmission to the image data evaluation device. Alternatively or in addition to providing the image data by a portable user device, it is also possible to arrange one or more image recording devices (for example cameras) on the measuring device (in particular the sample separation device) or in the surrounding region of the measuring device (in particular of the sample separation device). These cameras can be provided stationary or movable (for example rotatable, rotatable or movable). In this way, by capturing optical images from the meter or portions of the meter, image information may be provided, which may be evaluated, for example, by image recognition techniques to identify the fluid conduits, identify the modules, and / or couple modules Recognize fluid lines.

 According to one embodiment, the portable user device may be a smartphone. If the portable user device is designed as a smartphone, it can be benefited that smartphones usually also implement a camera that can be used to record the image data of the measuring device (in particular of the sample separation device). When using such a smartphone in connection with the device for elucidating the topology, an app can be installed on the smartphone, for example, before putting the first communication between the user device and the device into operation. This app may interact with software installed on the device, wherein communication may be via the communication devices of the devices and the portable user device. As an alternative to a smartphone, other portable user devices may also be used, for example a tablet computer, a personal digital assistant or another handheld device.

 According to one exemplary embodiment, the device or the arrangement or the measuring device may have a database with information for the correlation of image data or information extracted therefrom with modules and / or fluid lines. The device may be configured to access the database for determining the information indicative of the fluidic topology. If the device has identified the modules and fluid lines from the image data using methods of automatic object recognition (for example by reading a barcode attached thereto or the like), the identification information can be compared with information in a database via modules or fluid lines. For example, additional information about a module may be requested from the database that has been identified, for example, in terms of its product or order number. In this way, the communication between the mobile user device and device can be operated with a small amount of data, since required additional information can be queried from a separate database. For example, the database may be designed as an electronic mass storage, for example as a hard disk.

 According to one embodiment, the database may be cloud based. In other words, the database may be located at a node on the Internet or other communication network, and may be accessed from anywhere via the communication network. As a result, a database can be shared by many meters, which is a particularly resource-saving solution. Alternatively, the database can also be implemented as part of the device, that is, in particular be locally integrated in the measuring device.

 According to one embodiment, the portable user device may be configured to communicate control information to the device (for example, to control the operation of the meter). According to this embodiment, the user can keep the control in the interaction of the device and the portable user device. In particular, the topology determination can take place according to the specifications of a user on his mobile user device.

According to one embodiment, the portable user device and the measuring device (in particular the sample separation device) can communicate bidirectionally with one another in order to determine the information indicative of the topology in the context of a dialogue between the measuring device (in particular the sample separation device) and the portable user device. The communication between the device and the portable user device can therefore also be such that not one of these two nodes has a pure control function and the other node has a pure execution function. Instead, an interactive interaction between the portable user device and the device is made possible so that suggestions from the user can be transmitted to the device via its portable user device, can be evaluated by the device and can be returned with a corresponding suggestion. In such an architecture, a user may also respond to a request for the device in the affirmative, negative, or by submitting a counterproposal. The device assesses the suggestions of the user from factual points of view, for example, whether or not they are compatible with trouble-free operation of the meter. In this way, the willingness of a user can be increased to participate in the execution of embodiments, thereby contributing to the topology and the trouble-free operation of the meter.

 In one embodiment, the meter may include a controller configured to control operation of the meter (eg, to perform a particular chromatographic sample separation) based on the fluidic topology information of the meter. Such a control device can be designed, for example, as a processor, part of a processor or a plurality of processors, which can control the individual fluidic modules (and possibly the fluid lines) for carrying out a predetermined measuring operation. For refinement or clarification of the control, the control device can thus be supplied with the determined topology information.

 According to one exemplary embodiment, the determination device may be designed to determine the topology information based on the optically acquired image data from at least one part of the measurement device. One or more images of the fluidic measuring device allow the use of methods of image recognition (in particular pattern recognition by comparison with database information) to clarify the fluidic coupling between the modules and the fluid lines of the meter. For example, tube capillaries have a particular shape, size, and / or color, such that these fluid lines or fluidic connection elements on a picture are automatically recognizable. Also fluidic modules or nodes such as chromatography separation columns or chromatography high pressure pumps have a specific shape, size and / or color and are thus automatically identifiable on an image. The identification can be performed even more reliably and error-robustly if the fluidic nodes and / or the fluidic connection elements are provided with optically identifiable identification markers (for example a barcode or a QR code or an alphanumeric code) which reliably and optically detects the image data can be linked to database information.

 According to one exemplary embodiment, the image data can be detected by means of an image recording device of the measuring device. The measuring device itself can therefore have a camera or other image recording device which can record an image of the measuring device or of its fluidic coupling. By means of automatic image processing, the individual modules and fluid lines (possibly supported by markers attached thereto, barcode, QR code or the like for facilitating the optical detection or recognizability) and their fluidic coupling can be determined with one another.

 According to an exemplary embodiment, the image data can be captured by a user by means of a portable user device and the image data can be transmitted from the portable user device to the measuring device. For example, a user may be prompted to take a picture of the fluidic coupling of the meter with his mobile device having a camera (as a portable user device). This image can be evaluated to determine whether the fluidic topology can be clarified based on the image alone. If this is not the case, the user can be requested to record further specific image data. The meter may direct the user to provide specific missing information by taking additional pictures. In this way, the fluidic topology can be purposefully and completely cleared up.

 According to one embodiment, the measuring device can be designed as a sample separation device (in particular as a chromatographic sample separation device) for (in particular chromatographic) separation of a fluidic sample. However, other measuring devices are possible, for example a gel electrophoresis measuring device or a mass spectrometer.

 According to one embodiment, the sample separation device formed in particular as a chromatography apparatus may include a fluid drive (for example a chromatography high pressure pump) as one of the fluidic modules for driving the fluidic sample (eg a solvent or a solvent composition) in a mobile phase (eg measuring or separating biological sample), and having a sample separator (eg, a chromatography separation column) as another of the fluidic modules for separating the mobile phase fluid sample.

 The sample separation device may be a microfluidic measuring device, a life science device, a liquid chromatography device, a high performance liquid chromatography (HPLC), a UHPLC system, an SFC (Supercritical Liquid Chromatography) device, a gas chromatography device, an electrochromatography device, and / or a gel electrophoresis device , However, many other applications are possible.

For example, the fluid pump may be configured to charge the mobile phase at a high pressure, for example, from a few hundred bars up to 1000 bar and more, through the system. The sample separator may include a sample injector for introducing the sample into the fluidic separation path. Such a sample injector may comprise a syringe-dockable injection needle in a corresponding fluid path, which needle may be withdrawn from that seat to receive sample, wherein upon reintroduction of the needle into the seat, the sample is in a fluid path which, for Example, by switching a valve, can be switched into the separation path of the system, which leads to the introduction of the sample in the fluidic separation path.

 The sample separator may include a fraction collector for collecting the separated components. Such a fraction collector may carry the various components, for example, into different liquid containers. The analyzed sample can also be fed to a drain tank.

 Preferably, the sample separation device may comprise a detector for detecting the separated components. Such a detector may generate a signal which can be observed and / or recorded and which is indicative of the presence and amount of sample components in the fluid flowing through the system.

BRIEF DESCRIPTION OF THE FIGURES

 Other objects and many of the attendant advantages of embodiments of the present invention will be readily appreciated and become better understood by reference to the following more particular description of embodiments taken in conjunction with the accompanying drawings. Features that are substantially or functionally the same or similar are given the same reference numerals.

1 shows an arrangement with a portable user device and a sample separator as an example of a measuring device according to an exemplary embodiment of the invention.

2 shows an arrangement according to another exemplary embodiment of the invention for determining information indicative of a fluidic topology of a sample separator.

 The illustration in the drawings is schematic.

Before describing exemplary embodiments with reference to the figures, some basic considerations will be summarized based on which exemplary embodiments of the invention have been derived.

 According to an exemplary embodiment of the invention, an apparatus may be provided for automatically determining an actual configuration of a sample separation device (eg, an HPLC). This can be done according to an exemplary embodiment of the invention by an optical detection and evaluation of image data of the sample separation device (or another measuring device). This in turn allows a diagnosis by the device regarding the enlightened topology. If necessary, recommendations may be communicated to a user if the identified topology is considered problematic or faulty by the device. In particular, the communication between the user and the sample separation device can take place via a portable user device with camera function and display function (such as a mobile telephone). This also enables the implementation of augmented reality elements in such a communication system. For example, while determining the fluidic topology based on provided and meter-representing image data (eg, digital photos and / or videos), the software of the device may detect that configuration gaps or the like have occurred in determining the topology. A user may then be prompted to provide additional and specific limited image data to fill these gaps for better or more complete enlightenment of the topology that the device still lacks. The user can, via his portable user device, if this contains an image-capturing function, generate the additional image data accordingly and transmit it to the device. Such a communication architecture also allows the user to assist the user in the context of troubleshooting, error detection, or troubleshooting. The device and the portable user device can enter into dialogue with each other in order to solve in cooperation the task of clarifying the topology.

 For example, after delivery of individual HPLC modules to construct an HPLC sample separator, the device may guide the user through appropriate communication messages to the portable user device through an installation. After a successful deployment, the device may determine the fluidic topology and further determine whether the sample separation device is functioning in this manner and having all the information about the fluidic connections required for control of the sample separation device.

In another embodiment, in an already fully installed sample separation device, a user can get an introduction to this sample separation device, where appropriate, gaps in the already known topology of the device can be closed.

 According to an exemplary embodiment, therefore, a user interface or a man-machine interface can be created, which can display to a user on a portable user device, which images of the sample separation device are still needed to determine the topology. From a database that may be implemented, for example, in a cloud, the device may then obtain information about modules and / or fluid lines identified on the images.

 The communication between the portable user device and the device can take place, for example, by means of near field communication (NFC) or WLAN.

 According to an exemplary embodiment, the user is not only a recipient of a preset control, but has the freedom to co-design the enlightenment of the topology itself. For example, a user has the freedom to place a particular module at the top of a stack, since under certain laboratory conditions he can then provide better fluid delivery via a fluid line. The device can recognize this user-side configuration of the modules and fluid lines by means of the image data and adapt a control of the sample separation device accordingly. Thus, according to an exemplary embodiment, a topology or a configuration of a sample separation device can be determined by recording and evaluating optical data of the sample separation device. In this case, it is also preferable to generate a dialog between the device and the user via the portable user device, in the context of which the user has options for the progress of the topology education. When a user rejects a suggestion of the device, the device presents the user with an alternative suggestion.

1 shows an arrangement 140 from a measuring device in the form of a chromatographic sample separation device 10 and a portable user device 120 in the form of a smartphone. In particular, illustrated 1 the basic structure of an HPLC system as an example of the sample separation device 10 , as it can be used for example for liquid chromatography. A fluid pump or a fluid drive 20 as a fluidic module 102 containing solvents from a supply unit 25 as another fluidic module 102 supplied drives a mobile phase through a sample separator 30 (such as a chromatographic column), which includes a stationary phase and another fluidic module 102 forms. A degasser 27 as yet another fluidic module 102 can degas the solvents before they drive the fluid 20 be supplied. A sample application unit 40 , as another fluidic module 102 , is with a switching valve or fluid valve 95 equipped and between the fluid drive 20 and the sample separator 30 arranged to introduce a sample liquid in the fluidic separation path. The stationary phase of the sample separator 30 is intended to separate components of the sample. Another fluidic module 102 in the form of a detector 50 has a flow cell and detects separated components of the sample. A fractionator (which is also a fluidic module 102 can form) can be provided to issue separated components of the sample in designated container. Liquids no longer needed can be dispensed into a drain tank. Capillaries or hose connections form fluidic connection elements or fluid lines 104 and cause a fluidic coupling of the fluidic nodes or modules 102 ,

A control unit 70 controls the individual components 20 . 25 . 27 . 30 . 40 . 50 . 60 . 95 of the sample separator 10 ,

The order 140 according to 1 thus forms a fluidic sample separation device 10 from a plurality of modules 102 , a plurality of fluid lines 104 , by means of which the modules 102 are fluidly coupled to each other, and the control device 70 to control the individual modules 102 and thus the entire sample separation device 10 , In addition, according to 1 a device shown schematically there 100 provided for determining a topology of the fluidic coupling of the fluidic modules 102 by means of the fluid lines 104 indicative information based on captured image data is set up. This image data, which is the sample separator 10 be imaged, by means of a sample separation device 10 associated image recording device 114 (For example, a camera) and / or by means of an internal camera one communicable with the device 100 (see Communication Facilities 110 . 122 ) coupled portable user device 120 (In the illustrated embodiment, a smartphone with an app installed on it) generated and the device 100 transmitted. The topology made by means of the device 100 is determined, the device can 100 the control device 70 submit to the controller 70 this topology information for targeted control of the sample separation device 10 and its components (especially its modules 102 ) can use. Although in 1 the meter as chromatographic sample separator 10 For the purpose of chromatographic separation of a fluidic sample, other measuring devices can also be equipped with the automatic topology determination architecture according to an exemplary embodiment of the invention.

The device 100 So serves to determine the topology of the sample separation device 10 that is the fluidic coupling of the individual modules 102 by means of the individual fluid lines 104 , For this purpose, by means of one or more cameras of the image pickup device 114 and / or the portable user device 120 one or more images of the sample separation device 10 added. Using methods of automatic image processing and object recognition, the individual modules 102 recognized on one or more pictures. Also the fluidic connections between these modules 102 in the form of fluid lines 104 can be identified. More specifically, for each port or port (see reference numeral 131 in 2 ) of the modules 102 be determined whether from this port a fluid line 104 goes out and to which other port of another module 102 this fluid line 104 leads. Free ports can also be detected. After determining the topology of the device 100 So then what modules known 102 over which fluid lines 104 and which ports are fluidly connected to each other. This information is transmitted by the device 100 to the controller 70 so that they control the sample separator 10 That is, the performance of chromatographic separation analyzes, if necessary, can adjust accordingly.

2 shows an arrangement 140 for determining a topology of the fluidic coupling of modules 102 by means of fluid lines 104 a sample separator 10 indicative information according to an exemplary embodiment of the invention.

The order 140 has a sample separation device designed as a liquid chromatography apparatus 10 according to 1 on. In the 2 illustrated modules 102 may be a chromatographic sample separator 30 , a fluid drive 20 for driving a mobile phase with a high pressure of at least 1000 bar, a sample application unit 40 for introducing the fluidic sample into a fluidic path between the fluid drive 20 and the sample separator 30 and a detector 50 to detect the separated fluidic sample. The modules 102 can be combined as desired by a user. The sample separator 10 serves to separate a fluidic sample and has the modules shown 102 for providing a respective function in the context of separating the fluidic sample. In addition, in the sample separator 10 Capillaries as fluid conduits 104 provided by means of which the modules 102 are fluidically coupled. For this purpose, a respective fluid line 104 between two respective ports 131 two modules 102 fluid-tightly connected to a fluid through the respective fluid line 104 from a port 131 one of the modules 102 to another port 131 another module 102 to lead.

In addition, the arrangement contains 140 a portable user device 120 in the form of a smartphone for capturing image data (in particular static image data, ie photos, or dynamic image data, ie videos) of the modules 102 and the fluid lines 104 and for transmitting the image data to the device 100 ,

Furthermore, the device forms 100 for determining a topology of the fluidic coupling of the modules 102 by means of the fluid lines 104 indicative information part of the sample separation device 10 , The device 100 has a control device designed, for example, as a processor 70 to control the modules 102 for separating the fluidic sample using the information indicative of the topology. The device 100 also has an image data evaluation device 106 for evaluating at least part of the sample separation device 10 imaging image data, for example by pattern recognition in the image data. A detection device 108 also forms part of the device 100 and is for determining the information indicative of the topology based on the evaluated image data, for example, by using a pattern for describing the fluidic coupling of the modules from patterns recognized in the image data 102 through the fluid lines 104 and the ports 131 is produced.

A wireless communication device 110 the device 100 acts to communicate with a wireless communication device 122 of the portable user device 120 to use a camera of the portable user device 120 recorded, the sample separation device 10 receive image data. A user can use the smartphone by means of the image recording device integrated therein images of the sample separation 10 , individual modules 102 , single fluid lines 104 , or individual sections of modules 102 and / or fluid lines 104 do. Should the device 100 still lacking information to elucidate the topology, the device can 100 via the communication device 110 an image data request message to the portable user device 120 Submit, with the specifically defined and still missing, the sample separator 10 image data to be requested. Thus, the device is 100 formed by the portable user device 120 specifically such additional image data Required to close a gap in the already partially determined, for the topology indicative information needed.

Also, the device can 100 the portable user device 120 via the communication device 110 for operation of the sample separator 10 provide indicative information. The for the operation of the sample separator 10 indicative information may include information to assist the user in mounting the sample separator 10 can be an information on individual modules 102 and / or fluid lines 104 and / or may include suggestions for redesigning the topology and operational information.

In particular, the device can 100 the portable user device 120 via the communication device 110 for communicating with the portable user device 120 transmit data required by augmented reality.

In 2 is shown that the device 100 In addition, for example, a trained as a CCD camera or CMOS camera image pickup device 114 for capturing image data for transmission to the image data evaluator 106 having. The device 100 So can the image data to determine the topology of the image pickup device 114 and / or from the portable user device 120 and thus independently or user-assisted determine the topology.

The order 140 Moreover, it has a database, which is designed, for example, as an electronic mass storage (for example hard disk) and, for example, cloud-based 150 on. Here you can find information on the correlation of evaluated image data with information about modules 102 and fluid lines 104 be saved. The device 100 can be used to determine the information indicative of the topology on the database 150 access.

The portable user device 120 indicates the communication device 122 for bidirectional communicable coupling with the device 100 to transmit image data and communication messages. In particular, the portable user device 120 the device 100 via the communication device 122 Control information for controlling the operation of the sample separation device 10 to transfer. In addition, the portable user device 120 the sample separator 10 provide at least some of the image data required to elucidate the topology. The portable user device 120 and the sample separator 10 can communicate bidirectionally with one another to determine the information indicative of the topology in a dialogue between the sample separation device 10 and the portable user device 120 perform.

From the portable user device 120 recorded image data can by means of the two communication devices 110 . 122 the device 100 or the portable user device 120 the device 100 be transmitted. Still missing image information about parts of the sample separation device 10 To elucidate the topology of fluidic coupling, the device sends 100 the image pickup device 114 of the sample separator 10 and / or the portable user device 120 a corresponding communication message and requests additional image data. In this way, the topology can be elucidated in an interactive manner, essentially without redundant recording and evaluation of image information.

Are in the device 100 the modules 102 and the fluid lines 104 has been identified and its fluidic coupling has been determined, the device may 100 for example via their communication device 110 and a communication network 159 (as the public Internet) additional information about the modules 102 or fluid lines 104 from a cloud-based database 150 seek.

During the described discovery of the topology may be a dialogue between the portable user device 120 on the one hand and the device 100 to increase the willingness of the user to contribute to the topology education. In addition, the user may through installation or introduction of the sample separator 10 be guided through the addition of augmented reality elements for a user pleasant. This can further increase the willingness of users to use the system and thereby the information base of the controller 70 for the error-free or precise execution of a sample separation experiment by means of the sample separation device 10 to increase.

In the following, further applications and embodiments of the invention are described:
According to an exemplary embodiment, an actual, accurate and accurate system configuration in a guided tour of a user may be analyzed by augmented reality.

 Liquid chromatography systems are often composed of an array of individual modules, for example arranged as a tower. For certain features or functionalities, it is advantageous to know their stacking sequence or fluidic connection. The same applies to electrical connections, etc.

Particularly in a case where a specific starting feature is executed or a predicted behavior is displayed to a user, high accuracy depends on the actual routing of the hydraulic fluid lines between the modules. This is even more so when providing a liquid chromatography system having a more complex architecture, such as a 2D LC sample separator configured for MHC mode and / or column selection. In such a scenario, simply checking the correct routing is already an expensive task.

 In conventional liquid chromatography systems, there is a concept of connecting through a central IP address and scanning essentially all local links. This can be filed in the form of a table.

 However, there is a natural limitation in the sense that only digitally identifiable information can be collected. Either devices with communication intelligence or tags such as RFID tags or one-wire PROM tags can be used as the source of information. All other details must be set blind (assuming default configurations) or require a user to choose from a menu. This is expensive.

 To overcome these disadvantages of conventional systems, an architecture is created according to an exemplary embodiment in which a user with his portable user device downloads an app from the Internet and installs it on the smartphone or tablet. The app can then connect the user to a cloud and a local software-based tool, supported by the app.

 The camera of the portable user device can now be used as an image recording device for recording image frames, which can be displayed, for example, in overlay with product information on the display device of the portable user device. Such an augmented reality display can then be used to guide the user through the respective task, for example by displaying on the display device of the portable user device a specific position or a specific spatial area (for example by means of a pointer such as an arrow). that still lacks information. This missing information can indicate which areas of the sample separation device of the device are still missing, in order to omit the topology of the fluidic coupling (optionally additionally also of the electrical coupling) of the modules of the sample separation apparatus.

 In this way, a user can be accompanied on a guided tour through the sample separation device. This may direct the user from an outlet of the pumping module to an inlet of an injection system, while appropriate photo or video data may be used to identify the capillaries. Thus, according to exemplary embodiments of the invention, the image data may be static images of parts or the entire sample separation device, or video data showing the sample separation device in whole or in part. For example, on the display of the user device, an augmented reality element can display a zoom on a bar code to be able to detect part information by means of optical identification.

 Such a guided tour can give a user a positive experience. This can promote the user's willingness to help educate the topology. If the device recognizes that the configuration of the modules by the user is problematic or even erroneous, which may be done by comparison with an expected or desired configuration by the device, a user may be informed accordingly, for example by a flashing warning light or the indication that an appropriate operation should be avoided. If the image pick-up data picks up the liquid level of solvent containers of the sample separation apparatus, the apparatus can also ensure that the solvent supplies are sufficient to ensure, for example, an overnight operation. Should too little fluid be detected here, a user can be alerted to this problem.

 In a simple scenario, a chromatographic separation method may require that a particular chromatographic separation column or chromatographic separation column type be used. However, one day may be missing on such a pillar. In this way, the liquid chromatography system has no way to check the configuration for correctness. The same applies to a system without column compartment. In such a case, the user may be prompted to specify a portable user device that has image capturing capabilities, or even video capture capabilities, such as a smartphone. The camera of the smartphone is then used to capture an image of a portion or an entire sample separation device, while a detected frame of the liquid chromatography system can be displayed on the display device of the portable user device.

A display element (for example an arrow) may then be added to, for example, an outlet of Injection device to motivate the user to direct the camera in this area. By means of image recognition, the capillary connections can be identified from this point to the column used. Once the separation column actually used has been identified, it can also be surrounded by a frame and the arrow next pointed to a label on it. In this way, the user can be motivated to aim the camera at the column so that the column label can be completely detected.

 A positive detection can be documented in a configuration file and can be copied into a data file.

 In another scenario, a complex system configuration may be set up, for example, a 2D LC system with MHC functionality. There are several modules that can be used but can be distributed in both dimensions. As an example, one can use two identical pumps for the first dimension and the second dimension. At the same time, three identical valve actuators can be used, which can control a "heart-cutting" function of valves with multiple sample loops.

 There are several plausible arrangements that can be used, but all can lead to a proper sample separation. However, a control unit needs to know the actual routing of fluid connections to be able to properly control it. Therefore, either strict rules are required or the user can set up the corresponding functionality manually.

 By contrast, with a device according to an exemplary embodiment of the invention in combination with a portable user device, an image can be taken while the detected frame is displayed on the display device. A display element may guide the user to first point to a field for identifying the individual modules of the liquid chromatography system. The user may then be sequentially guided from the outlet to the inlet along the connected capillaries and may thereby identify both the fluid connections and associated function definitions and the volumes of sample loops and the like.

 Even in a complicated fluidic scenario, this step-by-step guided tour informs the user about an optimal setup. At the same time, he will receive a positive perception of the final configuration, which can be documented in a configuration file and copied into a data file.

 It should be noted that the term "comprising" does not exclude other elements and that the "on" does not exclude a plurality. Also, elements described in connection with different embodiments may be combined. It should also be noted that reference signs in the claims should not be construed as limiting the scope of the claims.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0309596 B1 [0002]

Claims (20)

Contraption ( 100 ) for determining an information indicative of a topology of a measuring device, in particular a sample separating device ( 10 ), with a plurality of modules ( 102 ) and the modules ( 102 ) fluidically coupling fluid lines ( 104 ), the device ( 100 ) comprises: an image data evaluation device ( 106 ) for evaluating at least part of the measuring device, in particular of the sample separating device ( 10 ), imaging image data; a determination device ( 108 ) for determining the information indicative of the topology based on the evaluated image data. Contraption ( 100 ) according to claim 1, comprising a communication device ( 110 ) for communicable coupling with a portable user device ( 120 ). Contraption ( 100 ) according to claim 2, wherein the communication device ( 110 ) is set up by means of the portable user device ( 120 ), the measuring device, in particular the sample separating device ( 10 ) to receive imaging image data. Contraption ( 100 ) according to claim 2 or 3, wherein the communication device ( 110 ), an image data request message to the portable user device ( 120 ), with which, in particular specifically defined, the measuring device, in particular the sample separating device ( 10 ), image data to be requested. Contraption ( 100 ) according to claim 4, wherein the communication device ( 110 ) is formed by the portable user device ( 120 ) to specifically request such additional image data needed to close a gap in an already partially determined topology indicative information. Contraption ( 100 ) according to one of claims 2 to 5, wherein the communication device ( 110 ), the portable user device ( 120 ) for a mode of operation of the measuring device, in particular of the sample separating device ( 10 ) to provide indicative information. Contraption ( 100 ) according to claim 6, wherein for the operation of the measuring device, in particular the sample separation device ( 10 ), indicative information is selected from a group consisting of information for assisting a mounting of the measuring device, in particular of the sample separating device ( 10 ), Information on individual modules ( 102 ) and / or fluid lines ( 104 ), Proposals to redesign the topology and operational information. Contraption ( 100 ) according to one of claims 2 to 7, wherein the communication device ( 110 ) for communicating with the portable user device ( 120 ) is formed using augmented reality. Contraption ( 100 ) according to one of claims 1 to 8, comprising at least one image recording device ( 114 ) for receiving at least part of the image data for transmission to the image data evaluation device ( 106 ). Measuring device, in particular sample separating device ( 10 ) for separating a fluidic sample, wherein the measuring device, in particular sample separating device ( 10 ), comprising: a plurality of modules ( 102 ) for providing a respective function in the context of the operation of the measuring device, in particular in the context of the separation of the fluidic sample; Fluid lines ( 104 ), by means of which the modules ( 102 ) are fluidly coupled; a device ( 100 ) according to one of claims 1 to 9 for determining a topology of the fluidic coupling of the modules ( 102 ) by means of the fluid lines ( 104 ) indicative information; and a control device ( 70 ) for controlling the modules ( 102 ), in particular for separating the fluidic sample, using the information indicative of the topology. A meter according to claim 10, further comprising at least one of the following features: one of the modules ( 102 ) is used as a sample separation device ( 30 ), in particular as a chromatographic sample separation device, further in particular as a chromatography separation column; one of the modules ( 102 ) is used as a fluid drive ( 20 ) for driving a mobile phase at a high pressure; one of the modules ( 102 ) is used as a fluid drive ( 20 ) for driving a mobile phase at a pressure of at least 100 bar, in particular at least 500 bar, further in particular of at least 1000 bar, formed; one of the modules ( 102 ) is used as a sample application unit ( 40 ) for introducing the fluidic sample into a fluidic path between a fluid drive ( 20 ) and a sample separator ( 30 ) educated; one of the modules ( 102 ) is used as a detector ( 50 ), in particular as a fluorescence detector or UV absorption detector, designed to detect the separated fluidic sample; one of the modules ( 102 ) is a sample fractionator ( 60 ) for fractionating the separated fluidic sample; the sample separator ( 10 ) is adapted to analyze at least one physical, chemical and / or biological parameter of at least one fraction of the fluidic sample; the sample separator ( 10 ) comprises at least one of a group consisting of a chemical, biological and / or pharmaceutical analysis apparatus and a chromatography apparatus, in particular a liquid chromatography apparatus, a gas chromatography apparatus, a supercritical liquid chromatography apparatus, an HPLC apparatus and a UHPLC apparatus; the sample separator ( 10 ) is designed as a microfluidic device; the sample separator ( 10 ) is designed as a nanofluidic device. Arrangement ( 140 ), comprising: a measuring device, in particular a sample separating device ( 10 ), according to claim 10 or 11; a portable user device ( 120 ) adapted to receive at least part of the image data and to transmit the captured image data to the device ( 100 ). Arrangement ( 140 ) according to claim 12, wherein the portable user device ( 120 ) is a smartphone. Arrangement ( 140 ) according to claim 12 or 13, comprising a database ( 150 ) with information on the correlation of image data with modules ( 102 ) and / or fluid lines ( 104 ), the device ( 100 ) for determining the information indicative of the topology on the database ( 150 ). Arrangement ( 140 ) according to one of claims 12 to 14, wherein the portable user device ( 120 ) a communication device ( 122 ) for communicable coupling with the device ( 100 ), in particular to transmit image data and / or communication messages. Arrangement ( 140 ) according to one of claims 12 to 15, wherein the portable user device ( 120 ), the device ( 100 ) To transmit control information. Method for determining a topology of a measuring device, in particular a sample separating device ( 10 ), with a plurality of modules ( 102 ) and the modules ( 102 ) fluidically coupling fluid lines ( 104 ) indicative information, the method comprising: evaluating at least a part of the measuring device, in particular of the sample separating device ( 10 ), imaging image data; Determine the information indicative of the topology based on the evaluated image data. Method according to claim 17, comprising at least one of the following features: wherein a portable user device ( 120 ) the measuring device, in particular the sample separation device ( 10 ) provides at least a portion of the image data; being a portable user device ( 120 ) and the measuring device, in particular the sample separating device ( 10 ) communicate bidirectionally with one another in order to determine the information indicative of the topology in the context of a dialogue between the measuring device, in particular the sample separating device ( 10 ), and the portable user device ( 120 ). Computer-readable storage medium in which a program for determining a topology of a measuring device, in particular a sample separating device ( 10 ), with a plurality of modules ( 102 ) and the modules ( 102 ) fluidically coupling fluid lines ( 104 ) indicative information, which program, if it is from one or more processors ( 100 . 120 ) executing or controlling the method according to claim 17 or 18. Program element for determining a topology of a measuring device, in particular a sample separating device ( 10 ), with a plurality of modules ( 102 ) and the modules ( 102 ) fluidically coupling fluid lines ( 104 ) indicative information, which program element, if it is from one or more processors ( 100 . 120 ) executing or controlling the method according to claim 17 or 18.

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