JP4917491B2 - Dilution apparatus, electrolyte analysis apparatus or biochemical analysis apparatus equipped with dilution apparatus, dilution liquid filling method, and dilution liquid filling program - Google Patents

Description

  The present invention relates to a diluting device, an electrolyte analyzer or a biochemical analyzer including the diluting device, a diluting solution filling method, and a diluting solution filling program.

  Conventionally, an electrolyte analyzer using an ion-selective electrode has been used as a device for measuring the concentration of electrolytes such as urine and serum. As such an electrolyte analyzer, a sample solution is produced by diluting a sample with a diluent, and the electromotive force of the generated sample solution and the electromotive force of a reference solution for comparison are measured. A device that measures the electrolyte concentration of a component to be measured contained in a sample solution based on measurement data of the sample solution and the reference solution is known.

  As a specific analysis procedure, first, a sample such as urine or serum is diluted with a diluent using a diluting device. Then, the diluted sample solution is guided to the electrode part (ion selective electrode), and the electromotive force of the sample solution is measured by the measurement part. Subsequently, the reference solution is guided to the electrode unit, and the electromotive force of the reference solution is measured by the measurement unit. Then, in the measurement processing unit, the electrolyte concentration of the sample is obtained from the difference between the electromotive force of the sample solution and the electromotive force of the reference solution.

  When measuring the electrolyte concentration of such an electrolyte analyzer, if the sample concentration is not kept constant, a measurement error occurs. Therefore, the diluting device needs to generate a sample solution having a constant concentration. That is, in the diluting device, it is necessary to fill the diluting container with the same specified amount of diluting solution each time. As an apparatus for which such a dilution accuracy is required, a biochemical analyzer such as a glucose analyzer can be cited in addition to the electrolyte analyzer. Therefore, as a device for supplying a certain amount of liquid, for example, an air buffer having a pressure sensor for measuring the internal air pressure and a control valve for adjusting the internal air pressure is used to supply a certain amount of chemical liquid or cleaning liquid. A technique described above has been proposed (see, for example, Patent Document 1 below).

JP 2007-51981

  However, even if the technique of Patent Document 1 described above is diverted to a diluting device, the technique of Patent Document 1 is configured to control the flow path and the amount of liquid using a syringe pump. There is a problem that the fluid system becomes complicated due to the configuration of switching. Moreover, since the technique of patent document 1 is a structure which uses a solenoid valve, in addition to cost increase, the malfunction of generation | occurrence | production of the measurement error by generation | occurrence | production of heat | fever, and a noise arises.

  In order to solve the above-described problems caused by the prior art, the present invention realizes a reduction in cost with a simple configuration, and a diluting device and a diluting device capable of keeping the diluting liquid in the diluting container at the same specified amount each time It is an object of the present invention to provide an electrolyte analyzer or a biochemical analyzer equipped with

  In order to solve the above-described problems and achieve the object, a diluting apparatus according to the present invention includes a diluting container for mixing a sample and a diluting liquid to produce a sample solution, and the diluting liquid in the diluting container. A supply pump for supplying the dilution liquid to the supply section, and a suction port for sucking the dilution liquid in the dilution container. The dilution liquid in the dilution container is set in advance. A suction nozzle in which the suction port is disposed at a height that is a specified water level, a discharge pump that discharges the diluent from the suction nozzle, and a height of the specified water level in which the suction port of the suction nozzle is provided A detection means provided at a high predetermined position for detecting the level of the dilution liquid in the dilution container supplied from the supply unit; and the dilution liquid in the dilution container is detected by the detection means by the detection means. Reaching position And a dilution control means for controlling the stop of the operation of the supply pump and the start of the operation of the discharge pump, and the dilution container has an opening, a cone shape or a spherical shape. The suction nozzle is fixedly disposed with the suction port positioned at the opening at the top of the housing, and the detection means is located at the opening more than the suction nozzle. It is fixedly arranged at a high position.

  Moreover, the diluting device according to the present invention, in the above-described invention, is a single straight path without a branch from the diluting solution storage unit storing the diluting solution to the supplying unit via the supply pump. And a discharge passage formed in a single straight passage without branching from the suction nozzle to the waste liquid storage portion through which the dilution liquid is discharged, from the suction nozzle. It is characterized by providing.

  Moreover, the dilution apparatus according to the present invention is characterized in that, in the above-described invention, the supply pump and / or the discharge pump uses a pump with an indefinite amount of delivery.

  In the dilution apparatus according to the present invention, the supply path and the supply unit are formed using a resin.

  An electrolyte analyzer or a biochemical analyzer according to the present invention is characterized by including the dilution device described above.

  In addition, the dilution liquid filling method according to the present invention includes a dilution container having an opening, a conical or spherical storage section, and a suction port for sucking the dilution liquid in the dilution container. A suction nozzle in which the suction port is fixedly arranged at a height at which the dilution liquid in the dilution container has a preset predetermined water level, and the suction port of the suction nozzle is provided in the opening. A dilution liquid filling method for a dilution apparatus, comprising a detection sensor provided at a predetermined position higher than a specified water level, wherein the dilution liquid is supplied to the dilution container using a supply pump. And a detection step of detecting the level of the dilution liquid in the dilution container supplied in the supply process using the detection sensor, and the dilution liquid in the dilution container is detected in the predetermined step by the detection process. Reached the position of Is detected, and a dilution control step for stopping the operation of the supply pump and starting an operation of a discharge pump for discharging the diluent from the suction nozzle, and a dilution control step for controlling the dilution from the suction nozzle And a discharging step of discharging the liquid.

  A diluent filling program according to the present invention causes a computer to execute the diluent filling method described above.

  According to the present invention, there is an effect that the dilution liquid in the dilution container can be kept at the same specified amount each time while realizing a reduction in cost with a simple configuration.

  Exemplary embodiments of a diluting apparatus, an electrolyte analyzing apparatus or a biochemical analyzing apparatus including the diluting apparatus, a diluting liquid filling method, and a diluting liquid filling program according to the present invention will be described below in detail with reference to the accompanying drawings. To do. In the following description, an electrolyte analyzer will be described as an example.

(Whole structure of the electrolyte analyzer 100)
FIG. 1 is an explanatory diagram showing the overall configuration of an electrolyte analyzer according to an embodiment of the present invention. In FIG. 1, the electrolyte analyzer 100 includes a sample supply unit 110, a dilution unit 120 as a dilution device, a measurement unit 130, and a waste liquid unit 140.

  The sample supply unit 110 includes a movable crane 111 that is movable in the X direction in the drawing by a moving mechanism (not shown), and a sample dispensing nozzle 112 provided in the movable crane 111. The sample dispensing nozzle 112 is connected to the dispensing pipe 113 and sucks and discharges the sample by the operation of a sample pump (not shown).

  A sample container 115 is provided in the middle of movement of the movable crane 111. In the sample container 115, a sample 116 such as urine or serum is accommodated. When the movable crane 111 moves and the sample pump performs a suction operation, the sample dispensing nozzle 112 dispenses a certain amount of the sample 116 from the sample container 115. Further, the movable crane 111 moves and the sample pump discharges, whereby the sample dispensing nozzle 112 dispenses the sampled sample 116 into the dilution pot 1231 of the dilution unit 120.

  The dilution unit 120 includes a diluent supply unit 1210, a diluent discharge unit 1220, and a sample dilution unit 1230. The diluent supply unit 1210 includes a diluent storage container 1211, a supply pump 1212, a supply pipe 1213 as a supply path, a supply nozzle 1214 as a supply unit, and a detection sensor 1215. The diluent supply unit 1210 sucks the diluent from the diluent storage container 1211 through the supply pipe 1213 by the operation of the supply pump 1212, and pours the diluent from the supply nozzle 1214 into the dilution pot 1231 as a dilution container. Put out.

  The supply pump 1212 is a piezoelectric element pump. Specifically, the supply pump 1212 has a built-in piezoelectric element and a check valve, and is a simple pump having no quantitativeness in the amount of liquid to be fed. The supply pipe 1213 and the supply nozzle 1214 are made of a non-metallic material, and specifically, for example, are made of synthetic resin. The supply pipe 1213 and the supply nozzle 1214 may be any one that can suppress the generation of rust and ions, and may use a natural resin such as rubber in addition to the synthetic resin. Further, the supply pipe 1213 is formed as a single straight passage without any branch from the diluent container 1211 to the dilution pot 1231 via the supply pump 1212.

  The detection sensor 1215 is, for example, a photo sensor, and detects whether or not the level of the diluent supplied in the dilution pot 1231 has reached a predetermined level. In addition to such a photo sensor, the detection sensor 1215 may be any sensor that can detect whether or not the water level in the dilution pot 1231 has reached a predetermined water level. There may be. Diluents include, for example, tris (hydroxymethyl) aminomethane aqueous solution, monoethanolamine aqueous solution, diethanolamine aqueous solution, triethanolamine aqueous solution, sulfuric acid, phosphoric acid, boric acid buffer, etc., and good buffers such as MOPS, HEPES, etc. Liquid is used.

  The dilution liquid discharger 1220 includes a discharge pump 1221, a suction nozzle 1222, a discharge pipe 1223 as a discharge path, and a waste liquid bottle 1224. The discharge pump 1221 is a piezoelectric element pump. Specifically, the discharge pump 1221 has a built-in piezoelectric element and a check valve, and is a simple pump having no quantitativeness in the amount of liquid to be fed.

  The suction nozzle 1222 discharges the diluent until the diluent reaches a specified water level by the operation of the discharge pump 1221. Although details will be described with reference to FIG. 3, the suction nozzle 1222 is provided with a suction port for sucking the diluent in the dilution pot 1231 on the lower surface, and the dilution liquid in the dilution pot 1231 has a high predetermined water level set in advance. The suction port is fixedly arranged. And when the water surface of the dilution liquid in the dilution pot 1231 reaches a specified water level, the suction nozzle 1222 stops the suction operation when a suction part that sucks the dilution liquid appears on the water surface of the dilution liquid. Yes.

  The discharge pipe 1223 is formed as a single straight passage without any branch from the dilution pot 1231 to the waste liquid bottle 1224 via the discharge pump 1221. With this configuration, the diluent discharge unit 1220 sucks the diluent from the dilution pot 1231 via the discharge pipe 1223 and discharges the excess diluent to the waste bottle 1224 by the operation of the discharge pump 1221. ing.

  The sample dilution unit 1230 includes a dilution pot 1231 as a dilution container and a stirring mechanism 1232. Although the dilution pot 1231 will be described in detail with reference to FIG. 3, the dilution pot 1231 is a container having an opening and a spherical storage portion. The suction nozzle 1222 described above is fixedly arranged with the suction port positioned above the dilution pot 1231. In addition, as shown in FIG. 7 to be described later, for example, a conical container may be used as the dilution pot 1231. Of course, it is also possible to use a cylindrical container.

  The stirring mechanism 1232 is provided inside the dilution pot 1231. The stirring mechanism 1232 mixes the sample 116 dispensed from the sample container 115 by a certain amount with the sample supply unit 110 and the diluent filled with a specified amount by the diluent supply unit 1210, for example, about 30 times the sample. To produce a homogeneous sample solution diluted. In the present embodiment, a dilution liquid is used as the reference liquid. When the electromotive force of the reference liquid (dilution liquid) is measured, only the dilution liquid is injected into the dilution pot 1231. In the dilution pot 1231, the stirred sample solution or the injected diluent as a reference solution (hereinafter referred to as measurement solution) is sent out from the dilution pot 1231 to the measurement unit 130.

  The measurement unit 130 includes a measurement pipe 131, a plurality of electrode units 132 (132a to 132d), an electromotive force measurement unit 133, and a measurement processing unit 134. The measurement pipe 131 is connected to the dilution pot 1231 and guides the measurement liquid in the dilution pot 1231 to the electrode unit 132.

  The electrode part 132 is provided on a path through which the measurement liquid passes. The electrode part 132 includes ion selective electrodes 132a to 132c and a comparison electrode 132d. The ion selective electrodes 132a to 132c are electrodes that output a potential sensitive to specific ions such as Na, K, and Cl, for example. The ion selective electrodes 132a to 132c and the comparison electrode 132d detect the respective potentials of the measurement liquid taken out from the dilution pot 1231 and sent from the measurement pipe 131. More specifically, the ion selective electrodes 132a to 132c and the comparison electrode 132d are arranged such that the measurement liquid sent from the measurement pipe 131 passes through the electrode part 132 and the ion selective electrodes 132a to 132c and the comparison electrode 132d. The potential difference between is detected.

  The electromotive force measurement unit 133 measures the electromotive force of each of the sample solution and the diluent that passes through the measurement pipe 131 through the electrode unit 132. Specifically, the electromotive force measurement unit 133 compares the potential detected by the ion selective electrodes 132a to 132c with each other when the sample solution or the reference solution is sent through the measurement pipe 131. The electromotive force is measured based on the potential detected by the electrode 132d. The measurement processing unit 134 measures the electrolyte concentration of the components to be measured (Na, K, Cl) contained in the sample solution based on the measurement results of the sample solution and the diluted solution measured by the electromotive force measurement unit 133.

  The waste liquid unit 140 includes a waste liquid pump 141, a waste liquid pipe 142, and a waste liquid bottle 143 (waste liquid bottle 1224). The waste liquid unit 140 sucks the measurement liquid from the dilution pot 1231 through the waste liquid pipe 142 and the measurement pipe 131 by the operation of the waste liquid pump 141, and discharges the measurement liquid to the waste liquid bottle 143. The waste liquid pump 141 is a piezoelectric element pump. Specifically, the waste liquid pump 141 has a built-in piezoelectric element and a check valve, and is a simple pump with no quantitativeness in the amount of liquid to be fed.

(Functional configuration of the electrolyte analyzer 100)
Next, a functional configuration of the electrolyte analyzer 100 according to the present embodiment will be described. FIG. 2 is an explanatory diagram showing a functional configuration of the electrolyte analyzer according to the present embodiment.

  In FIG. 2, the control unit 200 of the electrolyte analyzer 100 according to the present embodiment includes an electromotive force measurement unit 133, a measurement processing unit 134, and a dilution control unit 201. An operation unit 210 and a detection sensor 1215 are connected to the input side of the control unit 200, while a movable crane 111 (moving mechanism), a sample pump 230, and the like are connected to the output side of the control unit 200. The waste liquid pump 141, the display unit 220, the supply pump 1212, and the discharge pump 1221 are connected.

  The control unit 200 controls the entire electrolyte analyzer 100. Specifically, the control unit 200 receives a movable crane 111, a sample pump 230, a waste liquid pump 141, a display unit 220, and a supply pump based on a program stored in advance by input from the operation unit 210. 1212 and the discharge pump 1221 are controlled.

  In addition, the control unit 200 includes a dilution control unit 201. The dilution control unit 201 controls the dilution unit 120 and controls the supply pump 1212 and the discharge pump 1221 based on the detection result of the detection sensor 1215. Specifically, the dilution control unit 201 performs control to operate the supply pump 1212 until the detection sensor 1215 detects that the dilution liquid in the dilution pot 1231 reaches a predetermined water level, while the detection sensor 1215. When it is detected that the dilution liquid in the dilution pot 1231 reaches a predetermined water level, the operation of the supply pump 1212 is stopped and the operation of the discharge pump 1221 is started.

  For example, a keyboard is used as the operation unit 210, and operation input can be performed using keys for inputting characters, numbers, various instructions, and the like. The operation unit 210 may be a touch panel type input pad or a numeric keypad. The display unit 220 is a display screen such as a display, and displays the result measured by the measurement processing unit 134.

(Example of configuration of dilution unit 120)
Next, an example of the configuration of the dilution unit 120 used in the electrolyte analyzer 100 according to the present embodiment will be described with reference to FIG. FIG. 3 is an explanatory diagram showing an example of the configuration of the dilution unit used in the electrolyte analyzer according to the present embodiment.

  In FIG. 3, the dilution pot 1231 includes a spherical storage portion 311, a grip portion 312, and an opening 313. The dilution pot 1231 is fixed to the frame 301. Further, the supply nozzle 1214 and the suction nozzle 1222 are fixed to the arm 302 fixedly connected to the frame 301 so that no deviation occurs in the positional relationship with the dilution pot 1231 in the height direction.

  The supply nozzle 1214 is disposed at a height corresponding to the grip portion 312 and is disposed at a position higher than the suction nozzle 1222. The arrangement position of the supply nozzle 1214 is not limited to such a configuration, and may be arranged at an arbitrary position (height).

  On the other hand, the suction nozzle 1222 is formed in a cylindrical shape, for example, and is arranged with the suction port 322 for sucking the diluted solution as a lower surface. In particular, the suction nozzle 1222 needs to be in a certain positional relationship with respect to the dilution pot 1231 so that the position in the height direction does not shift. The height at which the suction port 322 is disposed is the specified water level. In addition, the suction port 322 is preferably positioned above the storage unit 311, and in the present embodiment, the suction port 322 is disposed at the height of the boundary between the storage unit 311 and the gripping unit 312 of the dilution pot 1231. .

  Further, the detection sensor 1215 only needs to be provided at a predetermined position higher than the height of the specified water level at which the suction port 322 is disposed. In the present embodiment, the detection sensor 1215 is positioned at a height corresponding to the grip portion 312. Specifically, it is disposed at a height between the supply port 321 and the suction port 322. The reason why the suction port 322 and the detection sensor 1215 are arranged in such a position is that the upper diameter is smaller than the bottom of the dilution pot 1231 and the area of the water surface of the diluted solution is reduced. It is because it can raise.

  The opening 313 of the dilution pot 1231 needs a certain area. The certain area is an area for securing a dispensing space by the sample dispensing nozzle 112 when the sample dispensing nozzle 112 is positioned in the opening 313 by the movable crane 111. Therefore, the opening 313 has an opening diameter enough to secure a space where the supply nozzle 1214, the suction nozzle 1222, and the sample dispensing nozzle 112 are located. According to the dilution pot 1231 having such a shape, the quantitative property for each measurement can be stably obtained.

(An example of the electrolyte analysis process of the electrolyte analyzer 100)
Next, an example of an electrolyte analysis process of the electrolyte analyzer 100 according to the present embodiment will be described with reference to FIG. FIG. 4 is a flowchart showing an example of an electrolyte analysis process of the electrolyte analyzer according to the present embodiment.

  In FIG. 4, the electrolyte analyzer 100 is in a standby state until an input for starting measurement is received from the operation unit 210 (step S401: No loop). When an input for starting measurement is received (step S401: Yes), dilution is performed. The unit 120 fills the dilution pot 1231 with a predetermined amount of the diluent in the diluent container 1211 (step S402). Details of the filling of the diluent in step S402 will be described later. Then, the sample supply unit 110 dispenses the sample in the sample container 115 into the dilution pot 1231 (step S403). Specifically, the sample dispensing nozzle 112 dispenses a predetermined amount of the sample 116 accommodated in the sample container 115 by the movement of the movable crane 111 and the operation of the sample pump 230, and this dispensing is performed. The sample is poured into the dilution pot 1231.

  Thereafter, the sample dilution unit 1230 agitates the diluted solution and the sample in the dilution pot 1231 by the agitation mechanism 1232 to generate a sample solution (step S404). Specifically, the stirring mechanism 1232 stirs the diluted solution and the sample, thereby generating a sample solution in which the sample and the diluted solution are uniformly mixed. Then, the electromotive force measurement unit 133 measures the electromotive force of the guided sample solution (step S405). Specifically, the sample solution generated in the dilution pot 1231 is taken out from the dilution pot 1231 by the operation of the discharge pump 1221 and guided to the measurement pipe 131.

  Then, the sample solution guided to the measurement pipe 131 passes through the electrode part 132. At this time, the electromotive force measurement unit 133 measures the electromotive force of the sample solution through the ion selective electrodes 132a to 132c and the comparison electrode 132d. And the waste liquid part 140 discharges | emits the sample solution after completion | finish of measurement (step S406). In this way, the measurement of the sample solution is completed.

  Next, measurement of the reference solution using the diluted solution is performed. The dilution unit 120 supplies a predetermined amount of the diluent in the diluent container 1211 to the dilution pot 1231 (step S407). Then, the electromotive force measurement unit 133 measures the electromotive force of the introduced diluent (Step S408). Thereafter, the waste liquid unit 140 discharges the diluted liquid after the measurement (step S409). In this way, measurement of the diluted solution as the reference solution is completed.

  And the measurement process part 134 measures the electrolyte concentration of the to-be-measured component contained in a sample solution based on the measurement result of a sample solution and a reference | standard solution (step S410). The display unit 220 displays the measurement result (step S411). Thereafter, the movable crane 111 is moved, and the sample dispensing nozzle 112 is cleaned at a cleaning position (not shown) (step S412). Specifically, for example, the movable crane 111 is moved, the sample dispensing nozzle 112 is placed at a predetermined cleaning position, and the sample dispensing nozzle 112 is cleaned using pure water. As for the cleaning of the dilution pot 1231, the dilution pot 1231 is also cleaned for the measurement because the dilution pot 1231 is filled with only the dilution liquid in the measurement of the dilution liquid.

  Then, based on the input information from the operation unit 210, it is determined whether or not there is a next sample measurement (step S413). If there is no next sample measurement (step S413: No), a series of processes is performed. Exit. On the other hand, in step S413, when the next sample is measured (step S413: Yes), the process proceeds to step S402.

(An example of a diluent filling process by the dilution unit 120)
Next, an example of the diluent filling process by the dilution unit 120 in the electrolyte analyzer 100 according to the present embodiment will be described with reference to FIG. FIG. 5 is a flowchart showing an example of a diluent filling process performed by the dilution unit in the electrolyte analyzer according to the present embodiment. The flowchart shown in FIG. 5 is processing in which step S402 of the flowchart shown in FIG. 4 is shown in detail.

  In FIG. 5, the dilution unit 120 operates the supply pump 1212 based on the control by the dilution control unit 201 (step S501). Then, it is determined whether or not the detection sensor 1215 has detected that the diluent supplied from the supply nozzle 1214 has reached a predetermined water level (step S502). In step S502, the process moves to step S501 and the supply pump 1212 is operated until the detection sensor 1215 detects that the diluent supplied from the supply nozzle 1214 has reached a predetermined water level (No in step S502). (Step S501).

  In step S502, when the detection sensor 1215 detects that the diluent supplied from the supply nozzle 1214 has reached a predetermined water level (step S502: Yes), the operation of the supply pump 1212 is stopped (step S503). . Then, the operation of the discharge pump 1221 is started (step S504), and a series of processes is ended. Thereafter, the diluent in the dilution pot 1231 is discharged until the suction port 322 appears on the water surface by the operation of the discharge pump 1221. The operation of the discharge pump 1221 may be stopped, for example, when a predetermined time has elapsed, or a sensor that can detect that the diluent has reached a specified water level is separately provided. You may make it prepare and stop based on the detection result of the said sensor. By such an operation, the diluted solution in the dilution pot 1231 can be kept at the same specified amount every time.

(Example of dilution operation performed by dilution unit 120)
Next, an example of dilution operation performed by the dilution unit 120 in the electrolyte analyzer 100 according to the present embodiment will be described with reference to FIGS. FIGS. 6A to 6C are explanatory diagrams illustrating an example of the dilution operation performed by the dilution unit in the electrolyte analyzer according to the present embodiment.

  As shown in FIG. 6A, the diluent is dispensed from the supply nozzle 1214 by the operation of the supply pump 1212. Then, as shown in FIG. 6B, when the level of the diluted solution poured into the dilution pot 1231 reaches a height that is detected by the detection sensor 1215, the supply pump 1212 stops its operation. Then, the discharge pump 1221 starts operating. By the operation of the discharge pump 1221, the diluent is sucked from the suction port 322 of the suction nozzle 1222. Note that the sucked dilution liquid is discharged to the waste liquid bottle 1224. Then, when suction from the suction port 322 of the suction nozzle 1222 is performed until the water level of the diluent reaches the level of the suction port 322, the suction port 322 appears on the water surface, and the diluent is sucked further. (See FIG. 6-3). In this way, the diluted solution has the same specified water level every time.

(An example of another shape of the dilution pot 1231)
Next, an example of another shape of the dilution pot 1231 used in the electrolyte analyzer 100 according to the present embodiment will be described with reference to FIG. FIG. 7 is an explanatory diagram showing an example of another shape of the dilution pot used in the electrolyte analyzer according to the present embodiment.

  A dilution pot 700 shown in FIG. 7 includes a conical storage portion 701, a grip portion 702, and an opening 703. The opening 703 needs a certain area. Specifically, the certain area is an area for securing a dispensing space by the sample dispensing nozzle 112 when the sample dispensing nozzle 112 is positioned in the opening 703 by the movable crane 111. Therefore, the opening 703 has an opening diameter enough to secure a space where the supply nozzle 1214, the suction nozzle 1222, and the sample dispensing nozzle 112 are located. Of course, it is possible to adopt a configuration in which the grip portion 702 is not provided.

  In addition, it is desirable that the detection position of the water level detected by the detection sensor 1215 and the position where the suction nozzle 1222 is arranged are positioned above the dilution pot 700. This is because the upper diameter is smaller than the bottom surface and the water surface area of the diluted solution is reduced, so that the detection accuracy and the suction accuracy can be increased. Thus, even with the dilution pot 700 shown in FIG. 7, the quantitativeness for each measurement can be stably obtained.

  As described above, the dilution unit 120 used in the present embodiment has the supply pump 1212 for supplying the diluent from the supply nozzle 1214 and the suction port 322 for sucking the diluent in the dilution pot 1231 on the lower surface. And a suction nozzle 1222 having a suction port 322 fixedly disposed at a height at which the dilution liquid in the dilution pot 1231 is set to a predetermined water level set in advance, a discharge pump 1221 for discharging the dilution liquid from the suction nozzle 1222, and a suction nozzle 1222 A detection sensor 1215 is provided at a predetermined position higher than the height of the specified water level where the suction port is provided, and detects the water level of the diluted solution in the dilution pot 1231 supplied from the supply nozzle 1214, and diluted by the detection sensor 1215. When it is detected that the diluent in the pot 1231 has reached a predetermined position, the supply pump 1212 Stop work, and a dilution control unit 201 for controlling the start of operation of the discharge pump 1221, and the like comprising a. Therefore, the dilution liquid in the dilution pot 1231 can be kept at the same specified amount each time with a simple configuration.

  Further, in the dilution section 120 used in the present embodiment, the supply pipe 1213 is a path formed from a diluent storage container 1211 to the dilution pot 1231 as a single straight path without branching, and the discharge pipe 1223 is The path from the suction nozzle 1222 to the waste liquid bottle 1224 is a path formed in one straight path without branching. According to such a configuration, the diluent supply unit 1210 and the diluent discharge unit 1220 do not need to use a solenoid valve, and are formed by a single straight passage, so that the fluid system can be simplified, Miniaturization can be realized and cost reduction can be achieved. Moreover, the environment-friendly dilution unit 120 can be provided without generating noise due to the electromagnetic valve.

  Further, in the diluting unit 120 used in the present embodiment, a piezoelectric element pump with an indefinite amount of feed is used for the supply pump 1212 and the discharge pump 1221. According to this configuration, since an inexpensive piezoelectric element pump is used, cost reduction can be realized.

  Moreover, in the dilution part 120 used for this Embodiment, the supply piping 1213 and the supply nozzle 1214 are formed from the non-metallic thing, and are formed using resin. According to such a configuration, it is possible to prevent the corrosion of the passage and the generation of ions, which are a concern when using metal.

  Moreover, in the dilution part 120 used for this Embodiment, the dilution pot 1231 (700) is provided with the opening part 313 (703) and the accommodating part 311 (701) formed in spherical shape or a cone shape. In the suction nozzle 1222, the suction port 322 is positioned above the housing portion 311 (701) and fixedly arranged. According to such a configuration, the area of the water surface of the diluted solution decreases as it goes above the storage unit 311 (701), so that the accuracy of suction can be increased, and the quantitative property for each measurement can be stably obtained. be able to.

  Moreover, according to the electrolyte analyzer 100 according to the present embodiment, it is possible to measure the sample solution diluted at the same concentration every time, and thus it is possible to perform stable measurement. Moreover, since the structure which does not equip a pump unit with a solenoid valve is realizable, heat_generation | fever can be suppressed and the stable measurement result can be obtained. In addition, noise due to the electromagnetic valve can be reduced, and the environment-friendly electrolyte analyzer 100 can be provided. Furthermore, since the supply pipe 1213 and the supply nozzle 1214 formed using a resin are provided, the corrosion of the passage and the generation of ions can be suppressed, and the measurement result can be stabilized.

  In the above description, the configuration in which the electrolyte analyzer 100 includes the diluting unit 120 has been described. However, the biochemical analyzer such as a glucose analyzer can also include the diluting unit 120. According to the biochemical analyzer provided with such a dilution unit 120, it is possible to perform stable measurement as in the case of the electrolyte analyzer 100 described above.

  As described above, according to the dilution apparatus, the electrolyte analysis apparatus or biochemical analysis apparatus including the dilution apparatus, the diluent filling method, and the diluent filling program, the dilution in the dilution pot 1231 supplied from the supply nozzle 1214 is performed. The liquid level is detected, and when it is detected that the diluted liquid in the dilution pot 1231 has reached a predetermined water level set in advance, the operation of the supply pump 1212 is stopped and the operation of the discharge pump 1221 is started. Therefore, the diluted solution in the dilution pot 1231 can be kept at the same specified amount every time with a simple configuration.

  The diluent filling method described in the present embodiment can be realized by executing a program prepared in advance on a computer such as a personal computer or a workstation. This program is recorded on a computer-readable recording medium such as a hard disk, a flexible disk, a CD-ROM, an MO, and a DVD, and is executed by being read from the recording medium by the computer. The program may be a transmission medium that can be distributed via a network such as the Internet.

  As described above, the diluting apparatus, the electrolyte analyzing apparatus or biochemical analyzing apparatus equipped with the diluting apparatus, the diluting solution filling method, and the diluting solution filling program measure the electrolyte concentration of a sample such as urine or serum. It is suitable for a diluting apparatus for diluting a sample with a diluent for biochemical analysis such as electrolyte analysis or glucose concentration measurement.

It is explanatory drawing which shows the whole structure of the electrolyte analyzer concerning embodiment of this invention. It is explanatory drawing which shows the functional structure of the electrolyte analyzer concerning this Embodiment. It is explanatory drawing which shows an example of a structure of the dilution part used for the electrolyte analyzer concerning this Embodiment. It is a flowchart which shows an example of the electrolyte analysis process of the electrolyte analyzer concerning this Embodiment. It is a flowchart which shows an example of the dilution liquid filling process which a dilution part performs in the electrolyte analyzer concerning this Embodiment. It is explanatory drawing which shows the example of a dilution operation | movement which a dilution part performs in the electrolyte analyzer concerning this Embodiment. It is explanatory drawing which shows the example of a dilution operation | movement which a dilution part performs in the electrolyte analyzer concerning this Embodiment. It is explanatory drawing which shows the example of a dilution operation | movement which a dilution part performs in the electrolyte analyzer concerning this Embodiment. It is explanatory drawing which shows an example of the other shape of the dilution pot used for the electrolyte analyzer concerning this Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Electrolyte analyzer 110 Sample supply part 111 Movable crane 112 Sample dispensing nozzle 113 Dispensing piping 120 Dilution part 130 Measurement part 140 Waste liquid part 200 Control part 201 Dilution control part 301 Frame 302 Arm 311 Storage part 312 Grasping part 313 Opening part 321 Supply port 322 Suction port 700 Dilution pot 701 Storage unit 702 Gripping unit 703 Opening unit 1210 Diluent supply unit 1211 Diluent storage container 1212 Supply pump 1213 Supply pipe 1214 Supply nozzle 1215 Detection sensor 1220 Diluent discharge unit 1221 Discharge pump 1222 Suction Nozzle 1223 Discharge piping 1230 Sample dilution part 1231 Dilution pot

Claims (7)

A dilution container for mixing a sample and a diluent to produce a sample solution;
A supply unit for supplying the diluent to the dilution container;
A supply pump for delivering the diluent to the supply unit;
A suction nozzle that sucks the diluent in the dilution container, and the suction nozzle is disposed at a height at which the dilution liquid in the dilution container has a preset predetermined water level;
A discharge pump for discharging the diluent from the suction nozzle;
Detecting means for detecting the level of the dilution liquid in the dilution container provided in a predetermined position higher than the height of the specified water level in which the suction port of the suction nozzle is provided; and
Dilution control means for controlling stop of operation of the supply pump and start of operation of the discharge pump when the detection means detects that the diluent in the dilution container has reached the predetermined position. and, with a,
The dilution container includes an opening, and a storage portion formed in a cone shape or a spherical shape,
The suction nozzle is fixedly disposed with the suction port positioned at an opening in the upper portion of the housing portion,
The diluting device according to claim 1, wherein the detecting means is fixedly arranged at a position higher than the suction nozzle in the opening . A supply path formed in a single straight path without branching from the diluent storage part in which the diluent is stored, to the supply part via the supply pump,
A discharge path formed in a single straight passage without branching from the suction nozzle to the waste liquid storage part through which the diluent is discharged via the discharge pump;
The dilution apparatus according to claim 1, further comprising:   The diluting apparatus according to claim 1 or 2, wherein the supply pump and / or the discharge pump uses a pump with an indefinite amount of delivery.   The dilution apparatus according to claim 2 or 3, wherein the supply path and the supply unit are formed using a resin. An electrolyte analyzer or a biochemical analyzer comprising the dilution device according to any one of claims 1 to 4. A dilution container having an opening and a storage part formed in a cone shape or a spherical shape;
  A suction nozzle for sucking the diluent in the dilution container, and the suction nozzle fixedly arranged at a height at which the dilution liquid in the dilution container has a predetermined water level set in advance;
  In the opening, a dilution sensor filling method of a dilution device comprising a detection sensor provided at a predetermined position higher than the height of a prescribed water level where the suction port of the suction nozzle is provided,
  A supply step of supplying the diluent to the dilution container using a supply pump;
  A detection step of detecting the water level of the diluent in the dilution container supplied in the supply step using the detection sensor;
  After detecting that the dilution liquid in the dilution container has reached the predetermined position by the detection step, the operation of the supply pump is stopped, and the dilution liquid is discharged from the suction nozzle. A dilution control process for controlling the operation of the discharge pump;
  A discharging step of discharging the diluent from the suction nozzle;
  A diluent filling method comprising the steps of: A diluent filling program for causing a computer to execute the diluent filling method according to claim 6.

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