JP6254898B2 - Analysis tools and analysis systems - Google Patents

Description

  The present invention relates to an analysis tool loaded in an analyzer and an analysis system using the same.

  An analysis system for performing an analysis process using the concentration of a specific component contained in a liquid as a specimen as an analysis target value is disclosed (for example, Patent Document 1). In patent document 1, it aims at environmental pollution investigation, and an analysis object value is the density | concentration of the heavy metal in a liquid. The analysis system introduces a predetermined amount of sample into the analysis tool. This analysis tool is intended to perform pretreatment such as removal of foreign substances necessary for analysis on a specimen. In addition, the analysis tool is provided with a plurality of electrodes that serve as interfaces when analysis is performed by an analyzer after a predetermined pretreatment. As described above, the concentration of the heavy metal of interest is analyzed by the analysis system including the analysis tool and the analysis device.

  However, there are a wide variety of analysis methods employed depending on the type of specimen and specific component. Among various analysis methods, there is a method required to position the analysis tool and the analysis device with a predetermined accuracy. However, in the analysis tool, a part (hereinafter referred to as an analysis element) where the positional relationship with the analysis apparatus in the analysis processing becomes a problem (hereinafter, analysis element) may be a part of the analysis tool. For example, when the analysis element is formed integrally with a housing, the housing is accurately positioned with respect to the analysis device in order to position the analysis element with a predetermined accuracy with respect to the analysis device. It means to do. However, dimensional accuracy is set in the housing in the manufacturing process, and deformation such as warpage inevitably exists. For this reason, it is difficult to position the analysis element with a desired accuracy by positioning the housing. Moreover, it is problematic in terms of cost mainly to manufacture the entire analysis tool including the housing with high accuracy and to position the analysis tool on the analysis device with high accuracy. On the other hand, in order to optimize costs, there is a concern that if the manufacturing accuracy of the entire analysis tool and the positioning accuracy between the analysis tool and the analysis device are improved, appropriate analysis cannot be performed or a more accurate analysis method cannot be adopted. Is done.

JP 2005-31050 A

  The present invention has been conceived under the circumstances described above, and it is an object of the present invention to provide an analysis tool and an analysis system capable of performing positioning required for analysis processing with higher accuracy. And

  An analysis tool provided by the first aspect of the present invention is an analysis tool that takes a loaded state loaded in an analyzer and an unloaded state not loaded in the analyzer, the casing and the housing An analytical element at least partially housed in a body, and in the unloaded state, the analytical element is movable relative to the housing, and in the loaded state, the analytical element comprises: Positioned with respect to the analyzer.

  In a preferred embodiment of the present invention, the apparatus further comprises urging means for urging a force that interacts with the casing and the analysis element, and the analysis element is provided in a reference portion of the analysis apparatus. The urging means urges a force that abuts the positioning portion and the reference portion in a loaded state attached to the analyzer.

  In a preferred embodiment of the present invention, when the analysis tool is in the unloaded state, the force biased by the biasing means is smaller than the force biased in the loaded state.

  In a preferred embodiment of the present invention, the biasing means does not bias a force in the unloaded state.

  In a preferred embodiment of the present invention, the analysis element has two positioning portions that are in contact with the two reference portions of the analysis device in different directions from each other, and in the loaded state, The two urging means for urging the force for bringing the two positioning portions and the two reference portions into contact with each other are provided.

  In a preferred embodiment of the present invention, the housing has a temporary reference portion that can come into contact with the analysis element in the unloaded state.

In a preferred embodiment of the present invention, when the analytical element is the placed on the instrumentation Hama state from the non instrumentation Hama state, contact between the analytical element with the temporary reference portion is released.

  In a preferred embodiment of the present invention, the analysis element guides the reference part to a position facing the positioning part when the analysis tool changes from the unloaded state to the loaded state. Have means.

  The analysis system provided by the second aspect of the present invention includes the analysis tool provided by the first aspect of the present invention, and the analysis apparatus loaded with the analysis tool.

  An analysis system provided by the third aspect of the present invention includes the analysis tool provided by the first aspect of the present invention, and the analysis device loaded with the analysis tool, and the analysis device. Comprises an analyzer-side guiding means for guiding the reference portion to a position facing the positioning portion when the analysis tool changes from the unloaded state to the loaded state.

  According to one aspect of the present invention, the housing and the analysis element can be positioned with different accuracy in positioning the analysis tool with respect to the analysis device. Accordingly, it is possible to relatively relax the positioning accuracy of the casing to an allowable level while selectively positioning the analysis element with high accuracy. Therefore, by positioning the analysis element with high accuracy, it is possible to avoid a complicated structure of the entire analysis tool or an excessive increase in manufacturing cost. As a result, positioning required for the analysis process can be performed. It can be performed with higher accuracy.

  Other features and advantages of the present invention will become more apparent from the detailed description given below with reference to the accompanying drawings.

It is sectional drawing which shows the analysis tool based on 1st embodiment of this invention. It is a principal part expanded sectional view which follows the II-II line of FIG. It is a principal part expanded sectional view which follows the III-III line of FIG. It is a principal part expanded sectional view which follows the IV-IV line of FIG. It is a schematic front view which shows the analysis system based on 1st embodiment of this invention. It is a principal part expanded sectional view which shows operation | movement of the analysis system of FIG. It is a principal part expanded sectional view which follows the VII-VII line of FIG. It is a principal part expanded sectional view which shows operation | movement of the analysis system of FIG. It is a principal part expanded sectional view which follows the IX-IX line of FIG. It is a principal part expanded sectional view which shows operation | movement of the analysis system of FIG. It is a principal part expanded sectional view which follows the XI-XI line of FIG. It is a principal part expanded sectional view which shows the modification of the analysis system shown in FIG. It is a principal part expanded sectional view which shows the analysis tool based on 2nd embodiment of this invention. It is a principal part expanded sectional view which shows operation | movement of the analysis system based on 2nd embodiment of this invention. It is a principal part expanded sectional view which shows the analysis tool based on 3rd embodiment of this invention. It is a principal part expanded sectional view which shows operation | movement of the analysis system based on 3rd embodiment of this invention. It is a principal part expanded sectional view which shows the analysis tool based on 4th embodiment of this invention. It is a principal part expanded sectional view which shows operation | movement of the analysis system based on 4th embodiment of this invention. It is a principal part expanded sectional view which shows the analysis tool based on 5th embodiment of this invention. It is a principal part expanded sectional view which shows operation | movement of the analysis system based on 5th embodiment of this invention. It is a principal part expanded sectional view which shows the analysis tool based on 6th embodiment of this invention. It is a principal part expanded sectional view which shows operation | movement of the analysis system based on 6th embodiment of this invention. It is a principal part expanded sectional view which shows operation | movement of the analysis system based on 6th embodiment of this invention. It is a principal part expanded sectional view which shows operation | movement of the analysis system based on 6th embodiment of this invention.

  Hereinafter, preferred embodiments of the present invention will be specifically described with reference to the drawings.

  1 to 4 show an analysis tool according to the first embodiment of the present invention. The analysis tool 1 </ b> A of the present embodiment includes a housing 4, an analysis element 6, a movable channel 44, an operation unit 71, and a waste liquid collection unit 72. In addition, the point provided with the movable flow path 44, the operation part 71, and the waste liquid collection | recovery part 72, and the specific structure of the housing | casing 4 mentioned later are required in an example of performing a predetermined pre-processing with respect to a test substance. Yes, it is not an essential component of the analysis tool according to the present invention. Furthermore, in the present embodiment, the analysis tool 1A is configured as a so-called disposable type tool that is discarded after one analysis.

  The use of the analysis tool and the analysis system according to the present invention is not limited at all, but in the present embodiment, the case where analysis is performed using the concentration of a specific component contained in a sample such as a human or animal body fluid as an analysis target value is taken as an example. explain. Furthermore, as an example of such an analysis, a configuration for analyzing the concentration of heavy metals such as mercury, cadmium, and lead contained in urine as a specimen, and particularly a configuration for analyzing the concentration of mercury will be given as a specific example.

  The casing 4 forms the outer shape of the analysis tool 1A and functions to accommodate other components. The material and shape of the housing 4 are not particularly limited, but in the present embodiment, a substantially rectangular parallelepiped housing 4 made of, for example, resin is employed. The housing 4 is provided with an introduction part 41, a plurality of mixed packages 42, and a mixing tank 43.

  The introduction part 41 is a flow path into which urine as a sample is introduced. Each of the plurality of mixture packages 42 is mainly filled with a mixture to be used for analysis pretreatment. As an example of the mixed package 42, a general blister pack can be adopted. The mixture package 42 having such a configuration can be appropriately charged into the mixing tank 43 by applying a pressing force from the outside.

  In the present embodiment, the mixture to be sealed in the three mixed packages 42 includes citric acid powder as a buffering agent and a first chelating agent used in a mixing and concentration process for urine described later. Examples thereof include a mixed powder with dithizone powder, nitric acid, and a thiopronin solution as a second chelating agent. In addition, it is good also as a structure which seals the citric acid as a buffering agent, and the dithizone as a 1st chelating agent in the to-be-mixed package 42 separately.

  The mixing tank 43 is a place where urine as a specimen is mixed with the mixture to be introduced from the plurality of mixture packages 42 described above. An opening that faces the movable flow path 44 is provided in the lower portion of the mixing tank 43. The opening may be provided with filter paper (not shown) used for pretreatment described later.

  The movable channel 44 is for forming a state in which the specimen discharged from the mixing tank 43 is directed to the waste liquid collection unit 72 and a state in which the sample is directed to the analysis element 6. The movable flow path 44 has a waste liquid flow path 441 and an analysis flow path 442. The movable channel 44 can be slid in the x direction by the operation of the operation unit 71. In the state where the movable flow path 44 is shown in FIG. 1, when the specimen is discharged from the mixing tank 43, it flows to the waste liquid collection unit 72 via the waste liquid flow path 441. When the movable channel 44 slides to the right by a predetermined amount by operating the operation unit 71, the sample discharged from the mixing tank 43 flows to the analysis element 6 via the analysis channel 442. The movable flow path 44 can be appropriately formed using, for example, a resin.

  The operation unit 71 is a part for sliding the movable flow path 44, and includes a belt-like sheet 711 and a winding unit 712. The belt-like sheet 711 is a belt-like sheet connected to the winding unit 712 and the movable flow path 44. The belt-like sheet 711 transmits a force for sliding the movable flow path 44. In addition, the belt-like sheet 711 may have a function of closing or opening the opening of the mixing tank 43. In this case, a sealing part that can shield the opening of the mixing tank 43 and a liquid passage part that can open the opening are provided at appropriate positions of the belt-like sheet 711. In addition, the portion for passing liquid may have a function of retaining the sample itself or a predetermined component contained in the sample or filtering out the predetermined component.

  As shown in FIGS. 2 to 4, the housing 4 is provided with a spring part 51 </ b> A and a spring part 52 </ b> A. Each of the spring part 51A and the spring part 52A corresponds to an example of an urging means in the present invention. Each of the spring part 51 </ b> A and the spring part 52 </ b> A urges a force that interacts with the housing 4 and the analysis element 6. This interaction means that, for example, in a state where the spring portion 51A urges a force, a force that is a relationship between an action and a reaction is applied to the housing 4 and the analysis element 6.

  The spring part 51 </ b> A and the spring part 52 </ b> A of this embodiment are parts where a part of the housing 4 is formed in a relatively elongated shape. Thereby, 51 A of spring parts urge the force which acts on ax direction by bending in ax direction. The spring portion 52A biases a force acting in the y direction by bending in the y direction. The urging means of the present invention is not limited to such a configuration, and can take various configurations. For example, the spring part 51A and the spring part 52A are not limited to a structure formed integrally with the housing 4; for example, the spring part 51A and the spring part 52A are configured by parts separate from the housing 4. Also good. Alternatively, the spring part 51 </ b> A and the spring part 52 </ b> A may be attached to the analysis element 6.

  The analysis element 6 is a part that is positioned with respect to the analyzer when the analysis process is performed on the specimen. In the present embodiment, a predetermined amount of sample that has been subjected to a predetermined pretreatment is introduced into the analysis element 6. The analysis element 6 is a place where at least a part of the analysis process is performed. Examples of analysis methods include optical measurement and electrochemical measurement. Optical measurement can be performed, for example, by measuring absorbance, transmittance, reflectance, and the like. In this case, examples of the analyzer include an atomic absorption photometer and a visible light absorption photometer. In the present embodiment, a case where optical measurement is used for analysis processing will be described as an example. In addition, in this embodiment, although the analysis element 6 is formed as a separate body from the housing | casing 4, this is only one aspect | mode of this invention. The analysis element 6 and the housing 4 may be configured to be able to move relative to each other. For example, in a configuration in which the analysis element 6 and the housing 4 are resin-molded using a mold, the analysis element 6 and the housing 4 are connected by a connecting member that does not hinder the relative movement between the analysis element 6 and the housing 4. May be connected.

  The shape and the like of the analysis element 6 are not particularly limited, but in the present embodiment, the analysis element 6 has a substantially rectangular parallelepiped shape. The analysis element 6 is provided with a positioning part 61A, a positioning part 62A, and a slope 65A. The positioning portion 61A is brought into contact with a reference portion of an analyzer described later by a force urged from the spring portion 51A. In the present embodiment, the positioning portion 61A is provided on the opposite side in the y direction with respect to the tip of the spring portion 51A. The positioning part 61A is configured as a part slightly recessed from the peripheral part, but this is only an example, and the specific configuration of the positioning part 61A is variously set. The positioning portion 62A is brought into contact with another reference portion of the analyzer described later by a force urged from the spring portion 52A. In the present embodiment, the positioning portion 62A is provided on the opposite side in the x direction with respect to the tip of the spring portion 52A. The positioning part 62A is configured as a part slightly recessed from the peripheral part, but this is an example, and the specific configuration of the positioning part 62A is variously set.

  The slope 65A corresponds to an example of the analysis tool side guiding means referred to in the present invention. In the present embodiment, the slope 65A is provided adjacent to the lower portion of the positioning portion 62A in the z direction in the figure, and is inclined so as to be located inward in the y direction as it goes downward in the z direction.

  As shown in FIGS. 2 to 4, the analysis element 6 is accommodated in an accommodation space formed in the housing 4. In the unloaded state in which the analysis tool 1A is not loaded in the analyzer described later, the tips of the spring part 51A and the spring part 52A of the present embodiment are in contact with the analysis element 6. However, by appropriately setting the size of the accommodation space and the dimensions of the spring part 51A and the spring part 51B, the distance between the housing 4 and the spring part 51A and the spring part 51B is the same as or slightly the outer shape of the analysis element 6. It is considered to be a great relationship. Thereby, the spring part 51A and the spring part 51B are not clearly bent and do not bias the force. As described above, in the housing space, the analysis element 6 changes its posture to the extent that it does not drop out of the housing 4 in any of the x direction, the y direction, and the z direction. Movement is restricted to the extent that it does not. In addition, in a non-loading state, the structure in which the tip of the spring part 51A and the spring part 52A is not in contact with the analysis element 6 may be used.

  The waste liquid recovery unit 72 is for receiving unnecessary urine and co-washing liquid discharged from the mixing tank 43 as waste liquid. The waste liquid recovery unit 72 can typically employ a polymer absorber, but is not limited thereto, and may be any object that can absorb a sufficient amount of waste liquid.

  Next, the operation of the analysis system using the analysis tool 1A will be described below.

  FIG. 5 shows an analysis system according to the first embodiment of the present invention. The analysis system 3A of the present embodiment includes an analysis tool 1A and an analysis device 2A. The analysis apparatus 2A is an apparatus for performing the above-described analysis, and has an analysis unit 24 for performing optical measurement in the present embodiment. Moreover, the analyzer 2A includes a loading unit 20 that positions the analysis tool 1A in a posture suitable for performing analysis in the analysis unit 24. The analysis tool 1A is loaded into the loading unit 20 of the analyzer 2A in the manner shown in the figure after, for example, urine as a sample is introduced from the introduction unit 41 with a dropper or a paper cup and poured into the mixing tank 43. Is done. In the present embodiment, the loading direction when loading the analysis tool 1A to the analyzer 2A is perpendicular to the y direction and inclined with respect to the x direction. For this reason, in the loading process of the analysis tool 1A, the analysis tool 1A proceeds to the left in the x-direction diagram and proceeds to the lower side in the z-direction diagram.

  6 and 7 show the analysis tool 1A and the analysis apparatus 2A after being inserted into the analysis apparatus 2A and immediately before the loading of the analysis apparatus 2A into the loading unit 20 is completed. As shown in these drawings, the analyzer 2A is provided with a reference part 21A and a reference part 22A. The reference part 21A and the reference part 22A are for positioning the analysis element 6 with respect to the analysis part 24 with a desired accuracy by contacting the positioning part 61A and the positioning part 62A of the analysis element 6. In the actual loading operation, the user moves and loads the analysis tool 1A to the fixed analyzer 2A. In the following drawings, for convenience of explanation, the analysis tool 1A (analysis element 6) is loaded. The situation in which the reference portion 21A and the reference portion 22A move relatively is shown as an equivalent situation. The reference portion 21A and the reference portion 22A are located to the left in the x direction and below the z direction with respect to the analysis element 6 immediately before the completion of loading.

  Further, when the loading of the analysis tool 1A is continued, the reference portion 21A and the reference portion 22A approach relatively to the analysis tool 1A (analysis element 6). As shown in FIG. 8, the reference portion 21A of the analyzer 2A and the positioning portion 61A of the analysis element 6 come into contact with each other. Further, as shown in FIG. 9, the upper end in the z direction of the reference portion 22 </ b> A contacts the inclined surface 65 </ b> A of the analysis element 6. In this state, the spring portion 51A and the spring portion 52A have not yet applied a force.

  Further, the loading of the analysis tool 1A is continued, and the loading of the analysis tool 1A into the loading unit 20 is completed. Thereby, the housing 4 of the analysis tool 1A is loaded into the loading unit 20 with a predetermined positioning accuracy, and is fixed to the loading unit 20 in the x direction, the y direction, and the z direction. At this time, as shown in FIG. 10, the analysis element 6 is relatively pushed to the right in the x direction in the figure by the reference portion 21A.

  Then, as shown in the figure, the spring part 51A is bent to the right in the x direction in the figure by the approach of the reference part 21A via 6. Accordingly, the spring portion 51A biases the analysis element 6 with a force toward the left in the x direction in the figure. As a result, the analysis element 6 firmly contacts the reference portion 21A in the positioning portion 61A.

  Further, as shown in FIG. 11, the reference portion 22 </ b> A rises relatively upward in the z direction in the figure with respect to the analysis element 6 while being in contact with the inclined surface 65 </ b> A of the analysis element 6. As a result, the reference portion 22A is guided to a position facing the positioning portion 62A. Then, the analysis element 6 is moved to the left in the y direction in the drawing to bend the spring portion 52A. For this reason, the spring part 52 </ b> A biases the force toward the analysis element 6. As a result, the analysis element 6 firmly contacts the reference portion 22A at the positioning portion 62A. Thus, the magnitude of the force urged by the spring portion 51A and the spring portion 52A is larger in the loaded state than in the unloaded state. Furthermore, this embodiment is an example in which no force is applied from the spring portion 51A and the spring portion 52A in the unloaded state.

  By completing the above loading process, as shown in FIGS. 10 and 11, the positioning of the analysis element 6 with respect to the analysis unit 24 is completed. This state is referred to as a loaded state. Note that the analysis unit 24 shown in the figure indicates a reference point of analysis corresponding to the optical axis or the like in, for example, optical measurement. The analysis element 6 is required to be positioned with a predetermined accuracy with respect to the reference point. For example, when analyzing the concentration of heavy metal in urine by optical measurement, the positioning accuracy of the analysis element 6 with respect to the analysis unit 24 is required to be about 20 μm or less, for example.

  The analysis tool 1A loaded in the loading unit 20 is fixed in the x direction, the y direction, and the z direction by a portion (partially not shown) constituting the loading unit 20. At this time, the housing 4 (analysis tool 1A) is positioned with a certain degree of accuracy with respect to the loading unit 20 (analysis apparatus 2A). However, the analysis element 6 of the analysis tool 1A and the analysis unit of the analysis apparatus 2A described above. It is allowed to be lower than the positioning accuracy with respect to 24.

  When the analysis tool 1A is loaded, the analysis device 2A starts preprocessing and analysis processing. Here, first, an example of pre-processing will be given below. For example, one mixed package 42 is pressed by a rod (not shown) provided in the analyzer 2A to release the encapsulation. In the mixed package 42, a buffer and a first chelating agent are enclosed. Citric acid is used as the buffering agent, and more specifically, it is enclosed in the mixed package 42 in a solid state typified by powder. As the first chelating agent, dithizone is enclosed in the mixed package 42 in a solid state typified by powder. The buffer may be enclosed in the mixed package 42 in a liquid state called a citrate buffer, for example. In this case, it is preferable that the first chelating agent is enclosed in a mixed package 42 different from the citrate buffer.

  After the citric acid as the buffering agent and dithizone as the first chelating agent are put into the mixing tank 43, the specimen, the buffering agent, and the first chelating agent are mixed by stirring. This stirring may be performed by repeatedly blowing and sucking into the mixing tank 43 by a nozzle (not shown) provided in the analyzer 2A. Then, the analysis tool 1A is allowed to stand. Thereby, the dithizone as a 1st chelating agent and the heavy metal in urine raise | generate a chelate reaction, for example, a dithizone-mercury chelate complex is formed. Since dithizone is not dissolved under the present buffer solution, the above-mentioned stirring can be expected to increase the probability of complex formation. Here, the filter paper provided in the opening of the mixing tank 43 is positioned in the opening of the mixed package 42. This filter paper does not permeate urine, dithizone-mercury chelate complex, etc., and keeps at least a part thereof.

  Next, the winding unit 712 is rotated to wind up the belt-like sheet 711 by a predetermined length. Thereby, the shielding part of the strip-shaped sheet 711 is moved from the opening of the mixing tank 43, and the liquid passing part of the strip-shaped sheet 711 is placed at a position facing the opening of the mixing tank 43. Next, the pressure in the mixing tank 43 is increased by, for example, discharging from the nozzle. This positive pressure can drain urine against the resistance of the filter paper. Therefore, for example, while being left in this state, the specimen (urine) is sent to the movable channel 44 through the filter paper. The sample is poured into the waste liquid recovery unit 72 via the waste liquid channel 441 and absorbed by the waste liquid recovery unit 72. Since the dithizone-mercury chelate complex does not dissolve in the specimen (urine) and maintains a solid state, it does not pass through the filter paper. As a result, urine that is excessive in the analysis can be discharged to the waste liquid collecting unit 72.

  Next, the second mixture package 42 is unsealed. The mixed package 42 is filled with nitric acid used for washing together, and the washing tank 43 is charged with nitric acid for washing. By introducing nitric acid, specific components in the urine such as components that interfere with measurement are dissolved. Then, for example, by increasing the pressure in the mixing tank 43, excess urine is collected in the waste liquid collecting unit 72 through the filter paper. By this co-washing, the mixing tank 43 and the urine as the specimen can be brought into a normal state suitable for analysis.

  Next, by rotating the winding unit 712 of the operation unit 71, the movable channel 44 is moved, and the analysis channel 442 is positioned immediately below the opening of the mixing tank 43. Subsequently, the third package to be mixed 42 is unsealed. The mixed package 42 is filled with a thiopronin solution as a second chelating agent, which is put into the mixing tank 43. The above-mentioned dithizone-mercury chelate complex is stored in the filter paper. Mercury in this dithizone-mercury chelate complex is transferred to thiopronin by a chelate reaction with a thiopronin solution as the second chelating agent, and a thiopronin-mercury complex begins to be formed. Then, for example, urine, a dithizone-mercury chelate complex, and a thiopronin solution are mixed by shaking the entire analysis tool 1A with the analyzer 2A. Thereby, formation of a thiopronin-mercury complex is promoted. After this, the analytical tool 1A is allowed to stand. Since the thiopronin-mercury complex is dissolved, the thiopronin-mercury complex is dissolved in the specimen (urine). As a result, the sample in the mixing tank 43 has a higher mercury concentration than the urine before processing.

  Next, a specimen containing a high concentration thiopronin-mercury complex is moved to the movable channel 44 through the filter paper, for example, by discharging from the nozzle. The movable flow path 44 is in a posture in which the analysis flow path 442 is located immediately below the opening of the mixing tank 43. Therefore, the sample is received by the analysis element 6 through the analysis flow path 442.

  Thereafter, mercury is analyzed by, for example, optical measurement in the analyzer 2A loaded with the analysis tool 1A. At this time, the analysis element 6 is positioned with a predetermined accuracy with respect to the reference point of the analysis unit 24 shown in FIG. In this state, by performing a predetermined process from the analysis unit 24 on the sample accommodated in the analysis element 6, the analysis for mercury in urine as the sample is completed.

  Next, the operation of the analysis tool 1A and the analysis system 3A will be described.

  According to the present embodiment, the casing 4 and the analysis element 6 can be positioned with different accuracy in positioning the analysis tool 1A with respect to the analysis device 2A. Accordingly, it is possible to relatively relax the positioning accuracy of the housing 4 to an allowable level while selectively positioning the analysis element 6 with high accuracy. Therefore, by positioning the analysis element 6 with high accuracy, the structure of the entire analysis tool 1A can be complicated and an excessive increase in manufacturing cost can be avoided, and positioning required for analysis processing can be performed with higher accuracy. Can be done.

  In the unloaded state, no force is applied from the spring portion 51A and the spring portion 51B. In particular, when the spring part 51A and the spring part 51B are made of resin or the like, the spring part 51A and the spring part 51B bias a force having an appropriate magnitude by a so-called creep phenomenon if the force is biased for a long period. It will deteriorate to the state that can not be. According to the present embodiment, it is possible to prevent the spring portion 51A and the spring portion 52A from deteriorating during a period in which the analysis tool 1A is distributed in the market or stored at the user's location. In addition, since the analysis element 6 is surrounded in the housing space of the housing 4 to the extent that it does not move unduly and the posture is not disturbed, the analysis can be appropriately started.

  By providing the spring part 51 </ b> A and the spring part 52 </ b> A for biasing forces in two different directions, the analysis element 6 can be accurately positioned two-dimensionally with respect to the analysis part 24. In the present embodiment, the loading direction coincides with the x direction when viewed in the z direction. For this reason, when the analysis tool 1A is loaded, the reference portion 21A is relatively close to the analysis element 6 from the front in the x direction. This is suitable for energizing the force that can reliably bring the reference portion 21A and the positioning portion 61A into contact with each other by using the force for loading the analysis tool 1A to bend the spring portion 51A with certainty. Yes.

  On the other hand, the y direction, which is the direction of the force biased by the spring portion 52A, is perpendicular to the x direction, which is the loading direction, when viewed in the z direction. For this reason, even if the analysis tool 1A is loaded, the reference portion 22A is not in a relationship of relatively approaching the analysis element 6 in the y direction. However, an inclined surface 65A as an analysis tool side guiding means is provided at a position adjacent to the positioning portion 62A of the analysis element 6. Accordingly, even in the y direction perpendicular to the loading direction, the reference portion 22A can be appropriately guided to a position facing the positioning portion 62A, and a sufficient force can be urged from the spring portion 52A. .

  12 to 23 show a modified example or another embodiment of the present invention. In these drawings, the same or similar elements as those in the above embodiment are denoted by the same reference numerals as those in the above embodiment.

  FIG. 12 shows a modification of the analysis tool 1A and the analysis apparatus 2A. In this modification, the analysis element 6 of the analysis tool 1A is not formed with the slope 65A as the analysis tool-side guiding means described above. On the other hand, an inclined surface 25A is formed on the reference portion 22A of the analyzer 2A. The inclined surface 25A corresponds to an example of the analyzer-side guidance means referred to in the present invention. The inclined surface 25A is provided near the upper end of the reference portion 22A, and is inclined so as to approach the analysis element 6 in the y direction as it goes downward in the z direction. In the loading of the analysis tool 1A, when the analysis element 6 comes into contact with the inclined surface 25A, the analysis element 6 moves to the left in the x-direction diagram as the reference portion 22A further rises relatively upward in the z direction thereafter. Be made. Then, in the loaded state in which the loading is completed, force is urged from the spring portion 52A, and the positioning portion 62A of the analysis element 6 comes into strong contact with the reference portion 22A.

  Also according to such a modification, positioning required for the analysis process can be performed with higher accuracy. Further, the specific configuration of the analysis tool side guiding means and the analyzer side guiding means referred to in the present invention is as long as they serve the function of guiding the reference portion of the analyzer to the position facing the positioning portion of the analysis tool. There is no particular limitation. Further, a configuration similar to the slope 65A described above may be provided at a position adjacent to the positioning portion 61A, or a configuration similar to the inclined surface 25A may be provided in the reference portion 21A. Furthermore, both the slope 65A and the slope 25A may be employed. Also in the following embodiments, the analysis tool side guiding means and the analyzer side guiding means referred to in the present invention may be appropriately employed.

  FIG. 13 shows a case where the analysis tool according to the second embodiment of the present invention is not loaded. The analysis tool 1B of the present embodiment includes a spring part 51B and a spring part 52B. Each of the spring part 51B and the spring part 52B is constituted by a string-wound spring made of metal. The spring part 51 </ b> B and the spring part 52 </ b> B are fixed to the housing 4. In the illustrated state, the tips of the spring part 51B and the spring part 52B are separated from or in contact with the analysis element 6, but the spring part 52B and the spring part 52B are not compressed. , Not energizing force. Moreover, in this embodiment, the analysis element 6 has the positioning part 61B and the positioning part 62B. The positioning part 61B and the positioning part 62B are configured by a part of the flat outer surface of the analysis element 6, and are flush with the peripheral part.

  FIG. 14 shows an analysis system 3B including the analysis tool 1B and the analysis device 2B, and the analysis tool 1B is in a loaded state loaded in the analysis device 2B. In this loaded state, the reference portion 21B of the analyzer 2B is in contact with the positioning portion 61B of the analysis element 6, and the reference portion 22B is in contact with the positioning portion 62B. In order for the reference part 22B to appear at a position facing the positioning part 62B, an analysis tool side guiding means similar to the slope 65A described above or an analyzer side guiding means similar to the inclined surface 25A may be appropriately employed. Further, since the spring portion 51B and the spring portion 52B are compressed, the spring portion 51A biases a force acting in the x direction, and the spring portion 52B biases a force acting in the y direction. ing. As a result, the analysis element 6 is firmly brought into contact with the positioning portion 61B and the positioning portion 62B with respect to the reference portion 21B and the reference portion 22B, and is positioned with respect to the analysis portion 24.

  Also according to this embodiment, positioning required for the analysis process can be performed with higher accuracy. Further, the spring part 51B and the spring part 52B constituted by metal string winding springs are suitable for energizing a relatively large force or moving the analysis element 6 more greatly, and further due to a creep phenomenon. There is an advantage that deterioration hardly occurs.

  FIG. 15 shows a case where the analysis tool according to the third embodiment of the present invention is in an unloaded state. 1 C of analysis tools of this embodiment are provided with the magnet part 511C, the magnet part 512C, the magnet part 521C, and the magnet part 522C. The magnet unit 511C is composed of a magnet attached to the housing 4, and the magnet unit 512C is composed of a magnet provided in the analysis element 6 at a position facing the magnet unit 511C in the x direction. The magnet portion 511C and the magnet portion 512C have different magnetic poles. Such a magnet portion 511C and a magnet portion 512C correspond to an example of an urging means in the present invention. Moreover, the magnet part 521C consists of a magnet attached to the housing | casing 4, and the magnet part 522C consists of a magnet provided in the analysis element 6 in the position which faces the magnet part 521C in ay direction. The magnet part 521C and the magnet part 522C have different magnetic poles. Such a magnet part 521C and a magnet part 522C correspond to an example of an urging means in the present invention.

  In the present embodiment, the attractive force generated in the magnet part 511C and the magnet part 512C is used. Accordingly, the positioning part 61C is located on the same side as the magnet part 511C and the magnet part 512C in the x direction. Similarly, the attractive force generated in the magnet part 521C and the magnet part 522C is used. Accordingly, the positioning part 62C is located on the same side as the magnet part 521C and the magnet part 522C in the x direction. Note that one or both of the magnet unit 511C, the magnet unit 512C, the magnet unit 521C, and the magnet unit 522C may use a repulsive force. In this case, since the direction of the urging force is reversed, the arrangement of the positioning portion 61A and the positioning portion 62A is appropriately changed accordingly.

  In the present embodiment, even in the unloaded state, each of the magnet portion 511C, the magnet portion 512C, the magnet portion 521C, and the magnet portion 522C urges the force. As shown in the figure, each of the magnet part 511C and the magnet part 512C and the magnet part 521C and the magnet part 522C may be brought into close contact with each other. A restricting member that causes the above may be provided in the housing 4 or the analysis element 6. The positioning parts 61C and 62C are not limited to the configuration using a part of the magnet part 512C and the magnet part 522C. For example, the positioning parts 61C and 62C are provided at positions avoiding the magnet part 512C and the magnet part 522C in the analysis element 6. A positioning surface or a concave portion can be appropriately employed.

    FIG. 16 shows an analysis system 3C including the analysis tool 1C and the analysis device 2C, and the analysis tool 1C is loaded in the analysis device 2C. In order to allow the reference portion 21C and the reference portion 22C to enter the illustrated positions in the transition to the loaded state, the above-described analysis tool side guidance means and analysis device side guidance means may be appropriately employed. In the present embodiment, the reference portion 21C enters between the magnet portion 511C and the magnet portion 512C, and the reference portion 22C enters between the magnet portion 521C and the magnet portion 522C. The positioning portion 61C is brought into contact with the reference portion 21C by the attractive force generated in the magnet portion 511C and the magnet portion 512C. Further, the positioning portion 62C is brought into contact with the reference portion 22C by the attractive force generated in the magnet portion 521C and the magnet portion 522C.

  Also according to this embodiment, positioning required for the analysis process can be performed with higher accuracy. In this embodiment, the magnitude of the force urged by the urging means in the unloaded state can be larger than the magnitude of the force urged by the urging means in the loaded state.

  FIG. 17 shows a case where the analysis tool according to the fourth embodiment of the present invention is not loaded. The analysis tool 1D of this embodiment includes a spring part 51D and a spring part 52D, a temporary reference part 541D, a temporary reference part 542D, a temporary positioning part 641D, and a temporary positioning part 642D.

  The spring part 51D and the spring part 52D have the same configuration as the spring part 51A and the spring part 52A in the analysis tool 1A described above. The temporary reference portion 541D and the temporary reference portion 542D are for temporarily positioning the analysis element 6 in the unloaded state. More specifically, two temporary reference portions 541D and two temporary reference portions 542D are provided, and these protrude from the housing 4 toward the analysis element 6. The two temporary reference portions 541D are arranged apart from each other in the y direction and protrude in the x direction. The two temporary reference portions 542D are spaced apart in the x direction and protrude in the y direction.

  The temporary positioning part 641D and the temporary positioning part 642D are for temporarily positioning the analysis element 6 in the unloaded state together with the temporary reference part 541D and the temporary reference part 542D. More specifically, two temporary positioning portions 641 </ b> D and two temporary positioning portions 642 </ b> D are provided, and these are constituted by concave portions provided in the analysis element 6. The two temporary positioning portions 641D are provided at positions corresponding to the two temporary reference portions 541D, and the two temporary positioning portions 642D are provided at positions corresponding to the two temporary reference portions 542D. Note that the concavo-convex relationship of the temporary reference portion 541D, the temporary reference portion 542D, the temporary positioning portion 641D, and the temporary positioning portion 642D may be opposite to the illustrated relationship.

  The tip of the spring portion 51D is located between the two temporary reference portions 541D (temporary positioning portion 641D) in the y direction. The tip of the spring portion 52D is located between the two temporary reference portions 542D (temporary positioning portion 642D) in the x direction.

  In the illustrated unloaded state, the spring part 51D and the spring part 52D are not deflected in a state where the temporary reference part 541D and the temporary positioning part 641D and the temporary reference part 542D and the temporary positioning part 642D are spaced from each other. It is a dimensional relationship that can take. However, if the temporary reference portion 541D tries to completely come out of the temporary positioning portion 641D in the x direction, the spring portion 51D is clearly bent and biased. Similarly, when the temporary reference portion 542D tries to completely come out of the temporary positioning portion 642D in the y direction, the spring portion 52D is clearly bent and biased. Therefore, unless a specific external force is applied, no force is applied from the spring portion 51D and the spring portion 52D, and the temporary reference portion 541D and the temporary positioning portion 641D are in contact with the temporary reference portion 542D and the temporary positioning portion 642D. Further, the position of the analysis element 6 with respect to the housing 4 is temporarily determined by the engagement relationship.

  FIG. 18 shows an analysis system 3D including the analysis tool 1D and the analysis device 2D, and the analysis tool 1D is loaded in the analysis device 2D. The relationship between the analysis tool 1D in the loaded state and the analysis device 2D is the same as the relationship between the analysis tool 1A and the analysis device 2A described above. That is, the positioning portion 61D and the positioning portion 62D of the analysis element 6 are brought into contact with the reference portion 21D and the reference portion 22D of the analyzer 2D by the force urged by the spring portion 51D and the spring portion 52D. Thereby, positioning with respect to the analysis part 24 of the analysis element 6 is achieved. Further, in the loaded state, the temporary reference portion 541D and the temporary positioning portion 641D are brought into contact with the temporary reference portion 542D and the temporary positioning portion 642D.

  Also according to this embodiment, positioning required for the analysis process can be performed with higher accuracy. Moreover, provisional positioning accuracy of the analysis element 6 in the unloaded state can be improved by providing the temporary reference portion 541D and the temporary reference portion 542D, and the temporary positioning portion 641D and the temporary positioning portion 642D. This has the advantage that the analysis element 6 can be prevented from improperly moving or disturbing the posture even when the analysis tool 1D is placed in a state where it receives excessive vibration during transportation or the like. .

  FIG. 19 shows a case where the analysis tool according to the fifth embodiment of the present invention is in an unloaded state. The analysis tool 1E of this embodiment includes a spring part 51E and a spring part 52E, a temporary reference part 541E, a temporary reference part 542E, a temporary positioning part 641E, and a temporary positioning part 642E. The spring part 51E and the spring part 52E have the same configuration as the spring part 51B and the spring part 52B in the analysis tool 1B described above. The temporary reference portion 541E, the temporary reference portion 542E, the temporary positioning portion 641E, and the temporary positioning portion 642E have the same configuration as the temporary reference portion 541D, the temporary reference portion 542D, the temporary positioning portion 641D, and the temporary positioning portion 642D in the analysis tool 1D described above. It is.

  In the present embodiment, the spring portion 51E and the spring portion 52E bias the force in the unloaded state. Accordingly, the temporary reference portion 541E and the temporary reference portion 542E, the temporary positioning portion 641E, and the temporary positioning portion 642E are positively in contact with each other.

  FIG. 20 shows an analysis system 3E including an analysis tool 1E and an analysis device 2E, and the analysis tool 1E is in a loaded state in which the analysis device 1E is loaded. The relationship between the analysis tool 1E in the loaded state and the analysis device 2E is the same as the relationship between the analysis tool 1B and the analysis device 2B described above. That is, the positioning part 61E and the positioning part 62E of the analysis element 6 are brought into contact with the reference part 21E and the reference part 22E of the analyzer 2E by the force urged by the spring part 51E and the spring part 52E. Thereby, positioning with respect to the analysis part 24 of the analysis element 6 is achieved.

  Also according to this embodiment, positioning required for the analysis process can be performed with higher accuracy. Further, since the spring part 51E and the spring part 52E positively bias the force in the unloaded state, the temporary positioning of the analysis element 6 can be performed more accurately. By adopting the metal spring part 51E and the spring part 52E, it is possible to avoid the deterioration of the spring part 51E and the spring part 52E in the unloaded state.

  FIG. 21 shows a case where the analysis tool according to the sixth embodiment of the present invention is in an unloaded state. The analysis tool 1F of the present embodiment includes a spring part 51F, a spring part 52F, and a spring part 53F, a positioning part 61F, a positioning part 62F, and a positioning part 63F. Each of the spring part 51F, the spring part 52F, and the spring part 53F has a configuration similar to the spring parts 51B and 52B described above. The spring part 51F, the spring part 52F, and the spring part 53F urge forces in three different directions. In the present embodiment, the spring portions 51F, the spring portions 52F, and the spring portions 53F are arranged at intervals of approximately 120 ° with the analysis element 6 as the center. This interval can be set arbitrarily. The positioning part 61F, the positioning part 62F and the positioning part 63F provided in the analysis element 6 are arranged at intervals of approximately 120 ° corresponding to the spring part 51F, the spring part 52F, and the spring part 53F.

  In the unloaded state, the spring part 51F, the spring part 52F, and the spring part 53F are not in a state of positively biasing the force. However, when an external force such as gravity is applied, a force acting in a direction that prevents the movement is biased from at least one of the spring portion 51F, the spring portion 52F, and the spring portion 53F.

  22 to 24 show an analysis system 3F including the analysis tool 1F and the analysis device 2F, and the analysis tool 1F is in a loaded state in which the analysis device 1F is loaded.

  In the example shown in FIG. 22, the analyzer 2F includes a reference unit 21F and a reference unit 22F. In the loaded state, the force that causes the positioning portion 61F of the analysis element 6 to contact the reference portion 21F is urged from the spring portion 51F, and the force that causes the positioning portion 62F of the analysis element 6 to contact the reference portion 22F from the spring portion 52F. Is energized. Thereby, the analysis element 6 is positioned with respect to the analysis part 24 of the analyzer 2F.

  In the example shown in FIG. 23, the analyzer 2F includes a reference unit 22F and a reference unit 23F. In the loaded state, a force that causes the positioning portion 62F of the analysis element 6 to contact the reference portion 22F is urged from the spring portion 52F, and a force that causes the positioning portion 63F of the analysis element 6 to contact the reference portion 23F from the spring portion 53F. Is energized. Thereby, the analysis element 6 is positioned with respect to the analysis part 24 of the analyzer 2F.

  In the example shown in FIG. 24, the analyzer 2F includes a reference unit 23F and a reference unit 21F. In the loaded state, the force that causes the positioning portion 63F of the analysis element 6 to contact the reference portion 23F is urged from the spring portion 53F, and the force that causes the positioning portion 61F of the analysis element 6 to contact the reference portion 21F from the spring portion 51F. Is energized. Thereby, the analysis element 6 is positioned with respect to the analysis part 24 of the analyzer 2F.

  Also according to this embodiment, positioning required for the analysis process can be performed with higher accuracy. Further, by providing a spring part 51F that urges forces in three different directions, a spring part 52F, and a spring part 53F, as shown in FIGS. 22 to 24, the reference part 21F that can be provided in the analyzer 2F, the reference Depending on the specific configuration of the portion 22F and the reference portion 23F, a positioning force can be appropriately biased. The analysis element 6 is not limited to a complete circular shape, and may be any shape that can be positioned as intended by the present invention. For example, by providing a part of the analysis element 6 with a plane, this plane may be used as the positioning portions 61F, 62F, 63F. When the direction in which the analysis element 6F is to be positioned is specified to some extent with respect to the analysis device 2F, only one of the positioning portions 61F, 62F, and 63F that is necessary may be employed. Since the analysis element 6 of the present embodiment is connected to the three spring portions 51F, 52F, and 53F, there is little possibility that the analysis element 6 rotates unjustly during positioning. For this reason, for example, it is also possible to position the analysis element 6 by providing one positioning part 61F by appropriately setting the position and shape of the positioning part 61F.

  The analysis tool and the analysis system according to the present invention are not limited to the above-described embodiments. The specific configuration of each part of the analysis tool and the analysis system according to the present invention can be varied in design in various ways.

  The analysis tool according to the present invention may be configured to include only one urging means. For example, the analysis tool 1A may include only the spring part 51A, or the analysis tool 1D may include only the spring part 51D. Even in this case, the analysis element can be positioned in the direction in which the biased force acts. Or the structure provided with three biasing means and three positioning parts may be sufficient as the analytical tool which concerns on this invention. In other words, in the above-described embodiment, in addition to the two urging means and the two positioning portions corresponding to the x direction and the y direction, the urging means and the positioning portion corresponding to the z direction may be provided. Or in the structure provided with two urging means and two positioning parts, the structure corresponding to az direction may be sufficient as any one of urging means and positioning parts. Furthermore, the analysis tool according to the present invention is not limited to one provided with a biasing means and a positioning portion for the analysis element. If the casing and the analysis element are movable with respect to each other, the casing and the analysis element can be separately positioned with different accuracy with respect to the analysis device, and the effect intended by the present invention is achieved. be able to.

1A to 1F Analysis tool 2A to 2F Analysis device 3A to 3F Analysis system 4 Case 41 Introduction part 42 Mixed product package 43 Mixing tank 44 Movable flow path 51A, 51B, 51D to 51F, 52A, 52B, 52D to 52F, 53F Spring part (biasing means)
511C, 512C, 521C, 522C Magnet part 541D, 542D, 541E, 542E Temporary reference part 6 Analytical elements 61A to 61F, 62A to 62F, 63F Positioning part 641D, 642D, 641E, 642E Temporary positioning part 65A Slope (analysis tool side guidance) means)
71 Operation unit 20 Loading unit 21A to 21F, 22A to 22F, 23F Reference unit 24 Analysis unit 25A Inclined surface (analyzer side guidance means)

Claims (9)

An analysis tool that takes a loaded state loaded in the analyzer and an unloaded state loaded in the analyzer,
A housing,
An analysis element at least partially housed in the housing,
In the unloaded state, the analytical element is movable relative to the housing;
In the loaded state, the analytical element is positioned relative to the analytical device ;
A biasing means for biasing a force that interacts with the case and the analysis element;
The analysis element has a positioning portion that comes into contact with a reference portion of the analyzer,
In the loaded state attached to the analyzer, the urging means urges a force for bringing the positioning portion and the reference portion into contact with each other . The analysis tool according to claim 1 , wherein when the analysis tool is in the unloaded state, the force biased by the biasing means is smaller than the force biased in the loaded state. The analysis tool according to claim 2 , wherein the biasing means does not bias a force in the unloaded state. The analysis element has two positioning portions that are in contact with the two reference portions of the analyzer in different directions from each other,
The analysis tool according to any one of claims 1 to 3 , further comprising two urging means for urging a force for bringing the two positioning portions and the two reference portions into contact with each other in the loaded state. . The analysis tool according to any one of claims 1 to 4 , wherein the casing includes a temporary reference portion that can come into contact with the analysis element in the unloaded state. Wherein the analytical element is placed in the instrumentation Hama state from said non instrumentation Hama state, contact between the analytical element with the temporary reference portion is released, the analysis tool according to claim 5. The analytical element, when the analysis tool takes the mounted state from the unloaded state, has an analysis tool side guide means for guiding a position facing the reference portion with the positioning portion, claims 1 to 6 The analytical tool according to any one of the above. The analytical tool according to any one of claims 1 to 7 ,
An analysis system comprising: the analysis device loaded with the analysis tool. The analytical tool according to any one of claims 1 to 7 ,
The analysis device loaded with the analysis tool,
The analysis system includes an analyzer-side guidance unit that guides the reference unit to a position facing the positioning unit when the analysis tool changes from the unloaded state to the loaded state.

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