JP2011099679A - Analyzing system and method for controlling the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an analyzing system capable of reducing the input work of an analyzing condition, preventing the input mistake caused by manual work and reducing the time and mistake from the installation of a sample to the start of analysis, and to provide a method for controlling the same. <P>SOLUTION: Data including the specifications of a separation column and the analyzing condition of an analyzer is read from a memory medium, the upper and lower limit values of the analyzing condition at the time when the separation column is used are read and it is searched whether there is the analyzing condition related to the component to be analyzed in the data. In a case that there is the analyzing condition, the analyzing condition is used to detect the separated component of the sample and, in a case that there is no analyzing condition, a screen for inputting a new analyzing condition is displayed on a display device. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an analysis system that separates and detects sample components using a separation column to acquire analysis information, and a control method thereof.

  An analysis system using a separation column, for example, a liquid chromatograph analyzer, injects an analysis sample upstream of the separation column while feeding an eluent to the separation column, and the components of the analysis sample separated in the separation column are detected. It is the structure detected by the instrument. In the case of a gas chromatograph, an inert gas such as nitrogen or helium is used instead of the eluent.

  When performing an analysis with a liquid chromatograph analyzer, the analyst can use the data sheet attached to the separation column that describes parameters related to the analysis performance unique to each separation column, application data published by the manufacturer, and papers. With reference to the above, various analysis conditions are input to a computer, an analysis method representing a procedure for executing one analysis is created, and an analysis operation is executed.

  The separation column is packed with a stationary phase, and the analytical sample is separated by passing a mobile phase such as an eluent containing the analytical sample in the stationary phase, and a detector provided on the downstream side of the separation column The components separated in are detected in order. Examples of the stationary phase include silica gel, polystyrene gel, and polymer.

  Since the inner diameter and length of the separation column, the type of stationary phase, the type of mobile phase, and the types of sample components to be measured are diverse, the number of combinations is enormous. In addition, there are analysis conditions such as the flow rate of the pump that flows the eluent, the mixing ratio when two liquids are used as the eluent, the setting of the gradient operation that changes this mixing ratio with time, and the temperature setting of the oven that heats the separation column. There are a wide variety. In order to obtain good analysis results, the analyst must determine appropriate analysis conditions, and conventionally, the analyst must rely on the analyst's experience and knowledge. Even if the analysis conditions are determined, there are many input items when inputting the analysis conditions to the analyzer, which takes time and may cause an input error.

  Therefore, it is easy to determine analysis conditions by preparing a computer and database in addition to the analysis device, storing existing analysis conditions and analysis conditions entered in the past in the database, and making it possible to refer to the database during analysis. Attempts have been made.

  For example, an RFID (Radio Frequency Identification) is added to the sample container as a non-contact type storage medium, and the control device reads the analysis conditions of the sample recorded in the RFID and transmits them to the data analysis processing unit. Reads an analysis condition based on the information from the database and transmits it to the control device, and the control device has proposed an analysis method and an analysis device for controlling the analysis operation of the analysis device based on the analysis condition (for example, a patent) Reference 1). According to this method and analysis apparatus, the analyst simply sets the sample container and instructs the start of analysis, and the analysis operation is automatically performed without inputting the analysis conditions. Analysis can be prevented. However, in the case of an unknown sample, since the analysis conditions cannot be set in advance, there is no information to be recorded in the RFID, and the analyst must manually input the analysis conditions. Furthermore, although the information indicating the performance of the separation column set before the analysis operation is different for each separation column, it must be input by the analyst, so that complete automation cannot be realized.

  On the other hand, a prior art for automating the analysis operation in consideration of information indicating the performance of the separation column has been disclosed (see, for example, Patent Document 2). Specifically, an RFID is added as a non-contact type tag to the separation column, and the transmission / reception control unit reads information on the separation column recorded in the RFID and transmits the information to the data analysis unit. The data analysis unit corrects the analysis conditions based on the read information about the separation column, and the analysis conditions are automatically or manually transmitted to the analysis apparatus, and the analysis apparatus starts an analysis operation according to the transmitted analysis conditions. In this prior art, the analysis conditions stored in advance in the data analysis unit are corrected based on the read information on the separation column, and the above-mentioned flow rate of the pump for flowing the eluent and two liquids are used as the eluent. The analysis conditions including measurement conditions such as the mixing ratio at the time, the setting of the gradient operation for changing the mixing ratio with time, and the temperature setting of the oven for heating the separation column are not taken into consideration.

  As described above, according to the prior art, the component of the analysis sample and the type of the separation column can be automatically specified, but it is difficult to automatically determine the analysis conditions automatically. In addition, the analysis conditions determined by the analyst as being optimal are not necessarily the optimal analysis conditions, and the best results may not be obtained. In such a case, the conventional method is to create several types of analysis methods by gradually changing the parameters of the analysis conditions that have been determined to be optimal, perform the analysis for that number, and select the best result from these methods. The same analysis is repeated many times, which takes time and requires many samples and eluents.

JP 2005-257548 A JP 2008-107136 A

  As described above, determination of analysis conditions and creation of analysis methods depend on the labor of the analyst, and it is necessary to take a complicated and time-consuming process. In addition, analysis conditions are manually input to create an analysis method. Therefore, the possibility of an input error occurring is not low.

  It is an object of the present invention to provide an analysis system and a control method thereof that can reduce the input work of analysis conditions, prevent manual input errors, and reduce the time and mistakes from sample setting to analysis start.

  In order to solve the above object, an embodiment of the present invention reads information stored in a storage medium that is attached to a separation column and stores information having at least the specifications of the separation column and the analysis conditions of the analyzer. The upper and lower limits of the analysis conditions when using the separation column are read out from the received information, the information is searched for whether there are analysis conditions related to the analysis target component, and the analysis target component is found in the information. If there is an analysis condition related to the sample, the separated component of the sample is detected using the analysis condition. If there is no analysis condition related to the component to be analyzed in the information, a new analysis condition input screen is displayed. It is configured to be displayed on the device.

  According to an embodiment of the present invention, there is provided an analysis system and a control method therefor, in which the input work of analysis conditions is reduced, input errors due to manual work are prevented, and the time and mistakes from sample setting to the start of analysis can be reduced. Can be provided.

It is a functional block diagram which shows the structure of a liquid chromatograph analyzer. It is a flowchart which shows a part of flow of the analysis execution program performed in a data analysis part. It is a flowchart which shows a part of flow of the analysis execution program performed in a data analysis part. It is a flowchart which shows a part of flow of the analysis execution program performed in a data analysis part. It is a block diagram which shows the interconnection of a some analyzer. It is a flowchart which shows a part of flow of the analysis execution program performed in a data analysis part. It is a flowchart which shows a part of flow of the analysis execution program performed in a data analysis part. It is a flowchart which shows a part of flow of the analysis execution program performed in a data analysis part. It is a flowchart which shows a part of flow of the analysis execution program performed in a data analysis part. It is a flowchart which shows a part of flow of the analysis execution program performed in a data analysis part. It is a flowchart which shows a part of flow of the analysis execution program performed in a data analysis part. It is a screen figure which shows the example of the screen displayed on the display of a display part. It is a screen figure which shows the example of the screen displayed on the display of a display part.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a functional block diagram showing a configuration of a liquid chromatograph analyzer according to an embodiment of the present invention. In the liquid feeding section 1, single or plural types of eluents that have entered the eluent container 2 are fed by a pump 3 with the flow rate adjusted by a valve (not shown). In the sample injection unit 4, a sample to be analyzed is injected into the eluent and sent to the separation column 6. The separation column 6 is placed in a column oven 5 and heated. The sample is separated for each component in the separation column 6, and each component is detected in turn by the detection unit 9 and discharged to the drain. The flow rate of the eluent in the liquid delivery unit 1, the sample injection amount in the sample injection unit 4, the temperature of the column oven 5, and the detector in the detection unit 9 are controlled by a processor provided in the apparatus control unit 10.

  As described above, there are many types of stationary phases packed in the separation column, such as silica gel, polystyrene gel, and polymer. In the case of a gas chromatograph analyzer, a capillary column with a narrow inner diameter may be used. Conventionally, the analyst refers to the data sheet attached to the separation column in which parameter information relating to the analysis performance specific to each separation column is described, application data published by the manufacturer, papers, etc. In addition to manually inputting conditions into the analyzer, the analysis schedule was also manually input, an analysis method representing one analysis procedure was created and registered in the analyzer, and the analysis operation was executed. Therefore, even if the analyst enters information incorrectly, it will not be corrected, so the analysis will be executed with the wrong analysis method, and a conclusion will be drawn based on the wrong analysis result at the time of data analysis The potential is great.

  Therefore, in the embodiment of the present invention, the configuration described in the above-mentioned Patent Document 2, that is, the RFID 7 storing the above-described information is attached to the separation column, and the information is received by the transmission / reception unit 8 provided in the column oven 5. A reading configuration was adopted. The operation of the transmission / reception unit 8 is controlled by the transmission / reception control unit 11. With this configuration, simply by setting the separation column 6 in the column oven 5 and starting the transmission / reception unit 8, the analysis condition relating to the separation column 6 can be automatically read by the analyzer.

  In FIG. 1, only one separation column 6 is displayed. However, in the case of the column oven 5 in which a plurality of separation columns can be set, the RFID 7 and the transmission / reception unit 8 are provided so that information on each separation column 6 can be read separately. Configuration is easy within the prior art.

  In this embodiment shown in FIG. 1, an RFID that is a non-contact type IC tag is cited as an example of a recording medium. RFID is a recording medium that is small and does not require a unique power supply, can be rewritten as well as read out data, has excellent environmental resistance, and is not affected by contamination with water, oil, chemicals, or ambient light. It is not limited to RFID, and any device having the same function may be used.

  The RFID 7 stores the specifications of the separation column 6. Specifically, the manufacturer name, brand name, manufacturing lot number or manufacturing number of the separation column, shape information such as the inner diameter and length of the separation column, type such as the material and size of the packing material, upper limit pressure that can be used, and usable Record the information related to the restrictions in setting the analysis conditions when using this separation column, such as the temperature range, information on unusable chemicals, and the upper limit of the injected sample volume. Further, the separation column is used to record the analysis condition and the result information when the analysis is performed using the standard sample as the sample, or the analysis condition and the result are written after the analysis is completed.

  When the recording capacity of the RFID is limited, the information related to the restriction item in the analysis condition setting in the above information may not be rewritten, and the analysis condition and the result information may be rewritten.

  The transmission / reception unit 8 that reads or writes information from the RFID 7 does not necessarily have to be in the column oven 5, and may be installed within a range in which transmission / reception with the recording medium 7 can be performed. The transmission / reception unit 8 is connected to the transmission / reception control unit 11 to control reading and writing.

  The data analysis unit 12 includes a processor, is connected to the detection unit 9, the device control unit 10, and the transmission / reception control unit 11, stores information on the RFID 7 transmitted from the transmission / reception control unit 11 in a storage unit (not shown), By executing the stored program, the analysis method based on the analysis conditions is determined, and the operation of each part of the analysis apparatus is controlled. The data analysis unit 12 accepts input from an input unit 13 such as a keyboard or mouse of a personal computer, or displays analysis conditions, analysis methods, analysis results, etc. on a display unit 14 such as a display or a printer. Or let it print.

  2 to 4 are flowcharts showing a part of the flow of the analysis execution program executed by the data analysis unit 12.

  In FIG. 2, first, the analyst sets the separation column 6 with the RFID 7 at a predetermined position of the liquid chromatograph analyzer, so that the apparatus control unit 10 determines whether or not the separation column 6 is installed at the predetermined position. Is confirmed (step 201). For the confirmation, a sensor (not shown) such as a contact type is provided in the installation part of the separation column 6 of the column oven 5, and the presence / absence of the installation is automatically transmitted from the sensor to the apparatus control unit 10 by a signal. When there are a plurality of separation columns 6, the installation status is confirmed for each separation column 6. When it is confirmed that the separation column 6 is installed at a predetermined position, the apparatus control unit 10 transmits a signal indicating installation completion to the data analysis unit 12. When the separation column is not installed at a predetermined position, the fact is displayed on the display unit 14 to alert the analyst, and the analyst installs the separation column again.

  After receiving the installation signal for the separation column 6, the data analysis unit 12 transmits a command for reading information recorded on the RFID 7 attached to the separation column 6 to the transmission / reception control unit 11. The transmission / reception control unit 11 reads the information recorded in the RFID 7 via the transmission / reception unit 8 and transmits the information to the data analysis unit 12 (step 202).

  Examples of information recorded in the RFID 7 include the separation column manufacturer name, brand name, production lot number or production number, shape information such as the inner diameter and length of the separation column, and the type and material of the separation column packing material and size. There is information on the parts related to the restrictions in setting the analysis conditions when using this separation column, such as the upper limit of usable pressure, usable temperature range, information on unusable chemicals, and the upper limit of the amount of injected sample. Further, there are analysis conditions when analyzing a standard sample and information on the results, usage history so far, analysis information when used, and information such as analysis results and analysis results. There are also analytical conditions such as the flow rate of the pump that flows the eluent, the mixing ratio when two liquids are used as the eluent, the gradient operation setting that changes this mixing ratio with time, and the temperature setting of the oven that heats the separation column. is there.

  When the storage capacity of the RFID 7 is limited and all of the above information cannot be stored, the reference value of the analysis condition is stored in a storage unit (not shown) of the data analysis unit 12 and a parameter different from the reference value is stored. Only the value may be stored in the RFID 7.

  The data analysis unit 12 compares the upper and lower limit values of various parameters among the analysis conditions read from the RFID 7 with the upper and lower limit values of parameters stored in advance in a storage unit (not shown), and the parameters read from the RFID 7 When the upper and lower limit values are more severe, the upper and lower limit values of the parameters stored in advance are rewritten and stored in the storage unit. The analysis operation is executed between the upper limit value and the lower limit value of the parameter (step 203).

  If the analysis target component of the sample is known, the analyzer measures the amount. If the component is unknown, the analyzer analyzes the component to clarify the component name and measures the amount. Even if the analysis target component of the sample is known, the analysis conditions may differ depending on the type of separation column. Therefore, in the embodiment of the present invention, the RFID in which the analysis conditions are stored in the sample container is not attached.

  Next, the analyst determines whether or not to input the component name from the input unit 13 when the component name to be analyzed is determined in advance, and does not input it when it is not determined. Therefore, the data analysis unit 12 determines that the component name to be analyzed is determined when it is input, and that it is not determined when it is not input (step 204). In the former case, the flowchart shown in FIG. Go to, and search using the component name as a keyword. In the latter case, a screen for inputting an analysis condition by the analyst is displayed on the display unit 14, and the analysis condition is input by the analyst (step 205). When the analyst inputs a plurality of component names, the analyst can select whether to search by the product of each component or by sum.

  The data analysis unit 12 determines whether or not the input analysis condition exceeds the upper and lower limit values of the parameters set in step 203 (step 206). By displaying a screen prompting the analyst to re-input, such as performing an analysis, the analyst re-enters the analysis conditions. If not, based on the input analysis conditions, the analysis is executed in accordance with an analysis start instruction from the analyst (step 207). When the analysis is completed, the data analysis unit 12 collects and analyzes the analysis result, and causes the display unit 14 to display it in a form that is easy for the analyst to understand, such as a graph (step 208).

  FIG. 3 shows a procedure in the case where the analysis target component name is known in step 204 of FIG. 2. The data analysis unit 12 determines whether or not this component name is included in the analysis conditions read from the RFID 7. (Step 301), if not included, the process proceeds to the flowchart shown in FIG. If it is included, the included analysis condition is extracted, and it is determined whether or not the parameter value of the analysis condition is within the upper and lower limit values set in step 203 of FIG. 2 (step 302). When there are a plurality of searched analysis conditions, all conditions are determined.

  When the value of the parameter of the analysis condition is within the upper and lower limit values set in step 203 of FIG. 2, the data analysis unit 12 sets the values of the various parameters of the analysis condition as the analysis condition, and the analysis method And the value is displayed in the area for displaying the analysis condition on the display unit 14 (step 303). The analyst confirms the analysis method including the analysis conditions displayed on the display unit 14, and inputs an instruction to execute the analysis, whereby the analysis is executed by this analysis method (step 304). When the analysis is completed, the data analysis unit 12 collects and analyzes the analysis result, and causes the display unit 14 to display it in a form that is easy for the analyst to understand, such as a graph (step 305).

  In step 302, if the analysis condition parameter exceeds the upper and lower limit values of the read parameter, the data analysis unit 12 displays an error message such as “exceeds the column use condition limiter” on the display of the display unit 14, for example. A message is sent to the analyst (step 306), and then a confirmation message as to whether or not to change the analysis conditions is displayed (step 307). When the analyst causes the analysis to be performed without changing the analysis conditions, the process proceeds to step 303, and the analysis is performed. When an instruction to change the analysis condition is input, the analyst inquires whether or not to input a change value of the analysis condition (step 308). When the analyst inputs the change value of the analysis condition, step 304 The analysis is executed according to the analysis conditions input by the analyst. If the analyst does not set the change value of the analysis condition, the procedure proceeds to the procedure shown in FIG.

  FIG. 4 shows the procedure in the case where the analyst does not input the change value of the analysis condition in step 308 of FIG. 3. The analysis condition stored in the storage unit of the data analysis unit 12 is searched and the same as the target component The component is searched for whether there is an analysis condition when the analysis is performed using a separation column of the same type and brand as the separation column 6 installed this time (step 401), and if not, the process proceeds to the flowchart shown in FIG. . If there is, it is determined whether or not the value of the retrieved analysis condition parameter is within the upper and lower limit values set in step 203 of FIG. 2 (step 402). 12 sets the values of various parameters of the analysis conditions as analysis conditions, configures the analysis method, and displays the values in the area for displaying the analysis conditions on the display unit 14 (step 403). The analyst confirms the analysis method including the analysis condition displayed on the display unit 14, and inputs an instruction to execute the analysis, whereby the analysis is executed by this analysis method (step 404). When the analysis is completed, the data analysis unit 12 collects and analyzes the analysis results, and causes the display unit 14 to display the graph and the like in a form that is easy for the analyst to understand (step 405).

  In step 402, if the analysis condition parameter exceeds the upper and lower limit values of the read parameter, the data analysis unit 12 displays an error message such as “exceeds the column use condition limiter” on the display of the display unit 14, for example. A message is sent to the analyst (step 406), and then a confirmation message as to whether or not to change the analysis conditions is displayed (step 407). When the analyst causes the analysis to be executed without changing the analysis conditions, the process proceeds to step 403 and the analysis is executed. If an instruction to change the analysis condition is input, the analyst inquires whether or not to input a change value of the analysis condition (step 408). If the analyst inputs the change value of the analysis condition, step 404 The analysis is executed according to the analysis conditions input by the analyst. If the analyst does not input the change value of the analysis condition, the process proceeds to the flowchart shown in FIG.

  FIG. 5 is a block diagram showing the interconnection of a plurality of analyzers, and the analyzer 15 including the data analyzer 12 includes the analyzer 17 including the data analyzer 16, the analyzer 19 including the data analyzer 18, or The single data analysis device 20 and the network 21 are interconnected to perform data communication. Further, it is also connected to the Internet 23 via the connector 22. In this way, by making it possible to share analysis conditions not only with a single analysis apparatus but also among a plurality of apparatuses, it is possible to increase the probability of obtaining desired analysis conditions. In addition, by connecting the analyzer to the Internet and providing an environment in which the Internet can be used in the data analysis unit of the analyzer, the database provided by the manufacturer of the separation column, the analyzer manufacturer, and the contract analyzer provide You can search the desired analysis conditions by connecting to the database of academic papers and academic papers.

  6 to 10 are flowcharts showing a part of the flow of the analysis execution program executed by the data analysis unit 12. FIG. 6 shows the procedure when the analysis condition is not searched in step 401 of FIG. 4 or when the analyst does not input the changed value of the analysis condition in step 408, and performs communication using the network shown in FIG. The analysis conditions stored in the storage units of the data analysis units 16 and 18 other than the storage unit of the data analysis unit 12 and other storage units are searched (step 601). For the same component as the target component, whether or not there is an analysis condition when analyzing using a separation column of the same type and the same brand as the separation column 6 installed this time is searched. Proceed to the flowchart shown. If there is an analysis condition, it is determined whether the parameter value of the searched analysis condition is within the upper and lower limit values set in step 203 of FIG. 2 (step 602). The data analysis unit 12 sets values of various parameters of the analysis conditions as analysis conditions, configures an analysis method, and displays the values in an area for displaying the analysis conditions of the display unit 14 (step 603). The analyst confirms the analysis method including the analysis conditions displayed on the display unit 14, and inputs an instruction to execute the analysis, whereby the analysis is executed with this analysis method (step 604). When the analysis is completed, the data analysis unit 12 collects and analyzes the analysis result, and causes the display unit 14 to display the graph and the like in a form that is easy for the analyst to understand (step 605).

  In step 602, if the analysis condition parameter exceeds the upper and lower limit values of the read parameter, the data analysis unit 12 displays an error message such as “exceeds the column use condition limiter” on the display unit 14. A message is sent to the analyst (step 606), and then a confirmation message as to whether or not to change the analysis conditions is displayed (step 607). If the analyst causes the analysis to be performed without changing the analysis conditions, the process proceeds to step 603, where the analysis is performed. If an instruction to change the analysis condition is input, the analyst inquires whether or not to input a change value of the analysis condition (step 608). If the analyzer inputs the change value of the analysis condition, step 604 is performed. The analysis is executed according to the analysis conditions input by the analyst. If the analyst does not input the change value of the analysis condition, the process proceeds to the flowchart shown in FIG.

  FIG. 7 shows the procedure when the analysis condition is not searched in step 601 of FIG. 6 or when the analyst does not input the change value of the analysis condition in step 608, and performs communication using the network shown in FIG. The data analysis unit 12 is connected to the Internet to search for analysis conditions. The data analysis unit 12 uses the same kind and the same brand separation column as the separation column 6 installed this time for the same component as the target component. A search is made as to whether or not the page is in the page or the article database (step 701). When searching, the display unit 14 displays that the Internet search is necessary, and starts the search according to an instruction from the analyst. Further, since it takes a long time to analyze all databases, the database candidate to be searched is displayed on the display unit 14, and the analyst indicates which database is to be searched.

  If the database is not searched, the process proceeds to the flowchart shown in FIG. If there is, it is determined whether or not the parameter value of the searched analysis condition is within the upper and lower limit values set in step 203 of FIG. 2 (step 702). 12 sets the values of various parameters of the analysis conditions as analysis conditions, configures the analysis method, and displays the values in the area for displaying the analysis conditions of the display unit 14 (step 703). The analyst confirms the analysis method including the analysis conditions displayed on the display unit 14, and inputs an instruction to execute the analysis, whereby the analysis is executed with this analysis method (step 704). When the analysis is completed, the data analysis unit 12 collects and analyzes the analysis results, and causes the display unit 14 to display the graph and the like in a form that is easy for the analyst to understand (step 705).

  In step 702, if the analysis condition parameter exceeds the upper and lower limit values of the read parameter, the data analysis unit 12 displays an error message such as “exceeds the column use condition limiter” on the display unit 14. A message is sent to the analyst (step 706), and then a confirmation message as to whether or not to change the analysis conditions is displayed (step 707). If the analyst causes the analysis to be executed without changing the analysis conditions, the process proceeds to step 703 and the analysis is executed. When an instruction to change the analysis condition is input, the analyst inquires whether or not to input a change value of the analysis condition (step 708). When the analyzer inputs the change value of the analysis condition, step 704 is performed. The analysis is executed according to the analysis conditions input by the analyst. If the analyst does not input the change value of the analysis condition, the process proceeds to the flowchart shown in FIG.

  In the above embodiment, the data analysis unit 12 connected to the analyzer used for measurement and the other data analysis unit are connected by a network and also connected to the Internet. If the data analysis unit 12 is not connected to other data analysis units via a network and is connected only to the Internet, the procedure shown in FIG. 6 is not executed. Further, when connected to another data analysis unit via a network but not connected to the Internet, the procedure shown in FIG. 7 is not executed.

  As described above, when the analysis condition is not found or when the procedure shown in FIGS. 6 and 7 is not executed, the search is performed on the separation columns having different brands. FIG. 8 shows a procedure in the case where the analysis condition cannot be searched even in the database on the Internet in step 701 in FIG. 7 or the analyst does not input the change value of the analysis condition in step 708 in FIG. When the procedure shown in FIG. 7 cannot be executed, the procedure is executed subsequent to step 601 or step 608 in FIG. When neither FIG. 6 nor FIG. 7 can be executed, the process is executed subsequent to step 401 or step 408 in FIG. First, the analysis conditions stored in the storage unit of the data analysis unit 12 are searched, and the same component as the target component is analyzed using a separation column of the same type as the separation column 6 installed this time but with a different brand. Whether there is an analysis condition at the time of the search is searched (step 801), and if not, the process proceeds to the flowchart shown in FIG. If there is, it is determined whether or not the parameter value of the searched analysis condition is within the upper and lower limit values set in step 203 of FIG. 2 (step 802). 12 sets the values of various parameters of the analysis conditions as analysis conditions, configures the analysis method, and displays the values in the area for displaying the analysis conditions on the display unit 14 (step 803). The analyst confirms the analysis method including the analysis condition displayed on the display unit 14, and inputs an instruction to execute the analysis, whereby the analysis is executed by this analysis method (step 804). When the analysis is completed, the data analysis unit 12 collects and analyzes the analysis results, and causes the display unit 14 to display the graph and the like in a form that is easy for the analyst to understand (step 805).

  In step 802, if the analysis condition parameter exceeds the upper and lower limit values of the read parameter, the data analysis unit 12 displays an error message such as “exceeds the column use condition limiter” on the display of the display unit 14. A message is sent to the analyst (step 806), and then a confirmation message as to whether or not to change the analysis conditions is displayed (step 807). When the analyst causes the analysis to be executed without changing the analysis conditions, the process proceeds to step 803 and the analysis is executed. If an instruction to change the analysis condition is input, the analyst inquires whether or not to input a change value of the analysis condition (step 808). If the analyzer inputs a change value of the analysis condition, step 804 is performed. The analysis is executed according to the analysis conditions input by the analyst. If the analyst does not input the change value of the analysis condition, the process proceeds to the flowchart shown in FIG.

  FIG. 9 shows a procedure when the analyst does not input a change value of the analysis condition in step 801 or 808 of FIG. 8, performs communication using the network shown in FIG. An analysis condition stored in a storage unit other than the storage unit is searched (step 901). The same component as the target component is searched for whether there is an analysis condition when using the separation column of the same type as the separation column 6 installed this time but using a different brand separation column. Proceed to the flowchart. If there is, it is determined whether or not the value of the parameter of the searched analysis condition is within the upper and lower limit values set at step 203 in FIG. 2 (step 902). 12 sets the values of various parameters of the analysis conditions as analysis conditions, configures an analysis method, and displays the values in an area for displaying the analysis conditions on the display unit 14 (step 903). The analyst confirms the analysis method including the analysis conditions displayed on the display unit 14, and inputs an instruction to execute the analysis, whereby the analysis is executed with this analysis method (step 904). When the analysis is completed, the data analysis unit 12 collects and analyzes the analysis result, and causes the display unit 14 to display the graph and the like in a form that is easy for the analyst to understand (step 905).

  In step 902, if the analysis condition parameter exceeds the upper and lower limit values of the read parameter, the data analysis unit 12 displays an error message such as “exceeds the column use condition limiter” on the display unit 14. A message is sent to the analyst (step 906), and then a confirmation message as to whether or not to change the analysis conditions is displayed (step 907). If the analyst causes the analysis to be performed without changing the analysis conditions, the process proceeds to step 903, where the analysis is performed. When an instruction to change the analysis condition is input, the analyst inquires whether or not to input a change value of the analysis condition (step 908). When the analyzer inputs the change value of the analysis condition, step 904 is performed. The analysis is executed according to the analysis conditions input by the analyst. When the analyst does not input the change value of the analysis condition, the process proceeds to the flowchart shown in FIG.

  FIG. 10 shows a procedure when the analysis condition is not searched in step 901 of FIG. 9 or when the analyst does not input a change value of the analysis condition in step 908, and performs communication using the network shown in FIG. The data analysis unit 12 is connected to the Internet to search for analysis conditions. The data analysis unit 12 is the same type as the separation column 6 installed this time for the same component as the target component, but the analysis conditions when using a separation column of a different brand are the homepage on the Internet, It is searched whether it exists in the application data collection page, the article database, etc. (step 1001). When searching, the display unit 14 displays that the Internet search is necessary, and starts the search according to an instruction from the analyst. Further, since it takes a long time to analyze all databases, the database candidate to be searched is displayed on the display unit 14, and the analyst indicates which database is to be searched.

  If the database is not searched, the analyst sets arbitrary analysis conditions (step 1006), and proceeds to step 1004 as indicated by the symbol H in the figure. If there is, it is determined whether or not the value of the parameter of the searched analysis condition is within the upper and lower limit values set in step 203 of FIG. 2 (step 1002). 12 sets the values of various parameters of the analysis conditions as analysis conditions, configures the analysis method, and displays the values in the area for displaying the analysis conditions of the display unit 14 (step 1003). The analyst confirms the analysis method including the analysis conditions displayed on the display unit 14, and inputs an instruction to execute the analysis, whereby the analysis is executed with this analysis method (step 1004). When the analysis is completed, the data analysis unit 12 collects and analyzes the analysis results, and causes the display unit 14 to display the graph and the like in a form that is easy for the analyst to understand (step 1005).

  In step 1002, if the parameter of the analysis condition exceeds the upper and lower limit values of the read parameter, the data analysis unit 12 displays an error message such as “exceeds the column use condition limiter” on the display of the display unit 14, for example. A message is sent to the analyst (step 1007), and then a confirmation message as to whether or not to change the analysis conditions is displayed (step 1008). When the analyst causes the analysis to be executed without changing the analysis conditions, the process proceeds to step 1003 and the analysis is executed. When an instruction to change the analysis condition is input, the analyst inputs an arbitrary analysis condition (step 1009), and proceeds to step 1004 as indicated by the symbol H in the figure, and the analysis condition input by the analyst. Analysis is performed according to

  FIG. 11 is a flowchart showing a part of the flow of the analysis execution program executed by the data analysis unit 12, and is a flowchart in which the order of the procedures shown in FIGS. 4, 6, and 7 is changed. First, the analyst sets the separation column 6 with the RFID 7 at a predetermined position of the liquid chromatograph analyzer, so the apparatus control unit 10 confirms whether or not the separation column 6 is installed at the predetermined position ( Step 1101). When it is confirmed that the separation column 6 is installed at a predetermined position, the apparatus control unit 10 transmits a signal indicating installation completion to the data analysis unit 12. When the separation column is not installed at a predetermined position, the fact is displayed on the display unit 14 to alert the analyst, and the analyst installs the separation column again.

  After receiving the installation signal for the separation column 6, the data analysis unit 12 transmits a command for reading information recorded on the RFID 7 attached to the separation column 6 to the transmission / reception control unit 11. The transmission / reception control unit 11 reads the information recorded in the RFID 7 via the transmission / reception unit 8 and transmits the information to the data analysis unit 12 (step 1102).

  Examples of information recorded in the RFID 7 include the separation column manufacturer name, brand name, production lot number or production number, shape information such as the inner diameter and length of the separation column, and the type and material of the separation column packing material and size. There is information on the parts related to the restrictions in setting the analysis conditions when using this separation column, such as the upper limit of usable pressure, usable temperature range, information on unusable chemicals, and the upper limit of the amount of injected sample. Further, there are analysis conditions when analyzing a standard sample and information on the results, usage history so far, analysis information when used, and information such as analysis results and analysis results. There are also analytical conditions such as the flow rate of the pump that flows the eluent, the mixing ratio when two liquids are used as the eluent, the gradient operation setting that changes this mixing ratio with time, and the temperature setting of the oven that heats the separation column. is there.

  When the storage capacity of the RFID 7 is limited and all of the above information cannot be stored, the reference value of the analysis condition is stored in a storage unit (not shown) of the data analysis unit 12 and a parameter different from the reference value is stored. Only the value may be stored in the RFID 7.

  The data analysis unit 12 compares the upper and lower limit values of various parameters among the analysis conditions read from the RFID 7 with the upper and lower limit values of parameters stored in advance in a storage unit (not shown), and the parameters read from the RFID 7 When the upper and lower limit values are more severe, the upper and lower limit values of the parameters stored in advance are rewritten and stored in the storage unit. The analysis operation is executed between the upper limit value and the lower limit value of the parameter (step 1103).

  If the analysis target component of the sample is known, the analyzer measures the amount. If the component is unknown, the analyzer analyzes the component to clarify the component name and measures the amount. Even if the analysis target component of the sample is known, the analysis conditions may differ depending on the type of separation column. Therefore, in the embodiment of the present invention, the RFID in which the analysis conditions are stored in the sample container is not attached.

  Next, the analyst determines whether or not to input the component name from the input unit 13 when the component name to be analyzed is known, and does not input it when the component name is unknown. Therefore, the data analysis unit 12 determines that it is known when the component name to be analyzed is input, and is unknown when the component name is not input (step 1104). If the component name to be analyzed is unknown, the analyst inputs arbitrary analysis conditions (step 1109), and the process proceeds to step 1110. If it is known, the information stored in the RFID 7 of the separation column 6 is searched for whether there is an analysis condition relating to the component name to be analyzed (step 1105). If yes, go to Step 1112. If not, the information stored in the storage unit of the data analysis unit 12 is searched for whether there is an analysis condition related to the component name to be analyzed (step 1106). If yes, go to Step 1112. In the case where the data analysis unit 12 is connected to the network 21 shown in FIG. 5, the analysis condition regarding the component name to be analyzed is included in the information stored in the storage unit of the other data analysis unit. It is searched whether or not there is (step 1107). If yes, go to Step 1112. If there is not, a search is made as to whether it is on a homepage on the Internet, a company application data collection page, a paper database, or the like (step 1108). If not, go to Step 1109.

  In step 1112, the data analysis unit 12 automatically sets analysis conditions obtained as a result of the search, and the process proceeds to step 1110. In step 1110, the analysis is executed in accordance with the analysis start instruction of the analyst based on the input analysis conditions. When the analysis is completed, the data analysis unit 12 collects and analyzes the analysis result, and displays it on the display unit 14 in a form that is easy for the analyst to understand, such as a graph (step 1111).

  12 to 13 are screen diagrams showing examples of screens displayed on the display of the display unit 14 shown in FIG. FIG. 12 shows an example of a screen displayed when an analyst inputs analysis conditions in step 205 of the flowchart shown in FIG. 2. The screen 1201 displays “pump”, “name of device or function”. “Pump gradient”, “sampler”, “oven”, and “detector” are displayed in tab form, and as shown in the figure, the flow rate and its pattern are displayed as items for “pump”.

  Since the default value previously input or the previous value is displayed on the screen, the analyst inputs the parameter to be changed, the number of analysis methods, and the like. An analysis condition method is created by instructing by clicking. In the example of FIG. 12, it is shown that four patterns of analytical methods for reducing the flow rate of the pump by 0.1 mL are created on the basis of 1.0 mL / min. Specifically, the analysis method for the flow rate of the pump is 4 analysis conditions of 0.9 mL / min, 0.8 mL / min, 0.7 mL / min, and 0.6 mL / min. Created as street.

  Similarly, for “pump gradient”, “sampler”, “oven”, and “detector”, analysis conditions are set and analysis methods are set. After that, a sequence table for continuous analysis is created.

  FIG. 13 shows a sequence table creation procedure, and the file names of a plurality of analysis methods are displayed on the screen 1301. What is described as “Flow” is a file related to the analysis method of the flow rate of the pump, “Flow 1.0” indicates an analysis condition with a flow rate of 1.0 mL / min, and “Flow 0.6” indicates that the flow rate is 0. An analysis condition of .6 mL / min is shown. “Gr” is a file of “gradient” analysis conditions. As the analysis sequence, for example, a reference flow rate of 1.0 mL / min and a change from a reference gradient of 40% to 60% are selected, and the flow rate is changed from this reference to 0.6 mL / min every 0.1 mL / min, When creating a sequence combining analysis conditions in which the gradient is changed from 35% to 65% and analysis conditions in which the gradient is changed from 30% to 70%, “Flow 1.0.mtd” and “Flow 0. 9.mtd, Flow 0.8.mtd, Flow 0.7.mtd, Flow 0.6.mtd, Gr40-60.mtd, Gr35-65.mtd, Gr30-70. Each file name of “mtd” is designated, and an analysis sequence using these analysis conditions as parameters is created in accordance with an instruction of the creation button 1302.

  In conventional control software for analyzers, only one analysis method can be selected in one sequence table. Therefore, when changing the analysis conditions, the analysis conditions are changed after one analysis is completed, and the analysis is performed. This work was necessary. In this embodiment, when creating an analysis sequence, a plurality of analysis methods can be selected, and all analyzes can be performed automatically in one analysis operation. An analysis system with high work efficiency can be obtained.

  As described above, according to a preferred embodiment of the present invention, information necessary for creating an analysis method is obtained from information on a separation column stored in a recording medium such as RFID and information on a component name to be measured. The software that controls the device automatically searches in the computer connected to the device and in the computer that forms a network with the computer. Can be eliminated, and erroneous input can be prevented.

  Further, according to a preferred embodiment of the present invention, the apparatus controls information necessary for creating an analysis method from information on a separation column stored in a recording medium and information on a component name to be measured. Since the software automatically searches the Internet, it is possible to eliminate the time for the analyst to search for analysis information that is unknown to the analyst.

  In addition, according to a preferred embodiment of the present invention, from the information on the separation column stored in the recording medium and the information on the name of the component to be measured, the shape of the separation column set in the apparatus is the same as that of the same type. Although it is a separation column, even for other brand separation columns, the software that controls the device automatically searches the Internet for the information necessary to create an analysis method, so that the analyst can save time and effort. Can be eliminated.

  Further, according to a preferred embodiment of the present invention, the analysis conditions found by searching the software controlling the apparatus from the information of the separation column stored in the recording medium and the information of the component name to be measured are automatically detected. Since it inputs into the analysis method and creates the analysis method, it is possible to prevent human input errors. In addition, it is possible to obtain an effect that unnecessary time and labor such as re-creation of an analysis method or re-analysis of an analysis method due to an input error can be saved.

DESCRIPTION OF SYMBOLS 1 Liquid sending part 2 Eluent container 3 Pump 4 Sample injection part 5 Column oven 6 Separation column 7 RFID
8 Transmission / reception unit 9 Detection unit 10 Device control unit 11 Transmission / reception control unit 12, 16, 18 Data analysis unit 13 Input unit 14 Display unit 15, 17, 19 Analysis device 20 Data analysis device 21 Network 22 Connector 23 Internet 1201, 1301 Screen 1202, 1302 Create button

Claims (12)

In an analysis system including an analysis unit that acquires analysis information on the components of the sample by separating the sample with a separation column, and a data analysis unit that controls the analysis unit,
A transmission / reception controller that reads out the information from a storage medium that stores information about the separation column;
From the information and the name of the component, a data analysis unit that retrieves analysis information that is different from the separation column and acquired using the same type of separation column;
An analysis system comprising: a control unit configured to control the analysis unit according to an analysis condition included in the analysis information related to the separation column of the same brand brand searched by the data analysis unit.   2. The analysis system according to claim 1, wherein the separation column of the same type is a separation column to which at least one of the same brand, the same outer shape, and the same packing material corresponds. In an analysis system for separating a sample with a separation column and detecting separated components of the sample,
A transmission / reception controller that reads the information stored in a storage medium that is attached to the separation column and stores information having at least the specifications of the separation column and the analysis conditions of the analyzer;
A storage unit for storing the information transmitted from the transmission / reception control unit;
Of the information stored in the storage unit, read the upper and lower limit values of the analysis conditions when using the separation column,
Search whether there is an analysis condition related to the component in the information stored in the storage unit,
If there is an analysis condition for the component in the information,
Detecting the separated components of the sample using the analysis conditions;
If there is no analysis condition for the component in the information,
An analysis system comprising a data analysis unit for displaying a new analysis condition input screen on a display device. In the description of claim 3,
The analysis system characterized in that the specification of the separation column is information on a part related to restrictions in setting analysis conditions when using the separation column. In the description of claim 3,
The analysis system is characterized in that the analysis condition is an analysis condition when a standard sample is used as the sample. In the description of claim 3,
The analysis system according to claim 1, wherein the storage medium is an RFID, and an analysis result according to an analysis condition when the analysis is performed using the standard sample is written.   7. The analysis system according to claim 6, wherein an analysis result obtained by performing the analysis under the new analysis condition is additionally written to the RFID. In a control method for an analysis system in which a sample is separated by a separation column and a separated component of the sample is detected,
Reading the information stored in a storage medium that is attached to the separation column and stores information having at least the specifications of the separation column and the analysis conditions of the analyzer;
Among the read information, read the upper and lower limits of the analysis conditions when using the separation column,
Search whether there is an analysis condition for the component in the information,
When there is an analysis condition related to the component in the information, the separated component of the sample is detected using the analysis condition. When there is no analysis condition related to the component in the information, a new An analysis system control method, comprising: displaying an analysis condition input screen on a display device; In the description of claim 8,
The method for controlling an analysis system, wherein the specification of the separation column is information on a part related to a restriction in setting analysis conditions when the separation column is used. In the description of claim 8,
The method for controlling an analysis system, wherein the analysis condition is an analysis condition when an analysis is performed using a standard sample as the sample. In the description of claim 8,
The method of controlling an analysis system, wherein the storage medium is an RFID and an analysis result according to an analysis condition when the analysis is performed using the standard sample is written.   12. The analysis system control method according to claim 11, wherein an analysis result obtained by performing the analysis under the new analysis condition is additionally written to the RFID.

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