JPH07140150A - Automatic analyzer - Google Patents

Abstract

PURPOSE:To provide a small-sized automatic analyzer having simple structure. CONSTITUTION:The automatic analyzer 31 comprises a dilution pot 2 containing a diluted sample 16, a sample probe 3 for delivering a sample 6 to the dilution pot 2, and a rod 4 inserted into the dilution pot 2 and stirring the diluted sample 16, wherein the stirring rod 4 is fixed at a predetermined position while being inserted into the dilution pot 2 and inclined with respect to the dilution pot 2.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic analyzer for automatically measuring electrolyte concentration, for example.

[0002]

2. Description of the Related Art For example, there is a case where a dilution type automatic analyzer 1 as shown in FIG. 6 is used to measure an electrolyte such as serum or urine. This automatic analyzer 1 is equipped with a dilution pot 2, a sample probe 3, a stirring rod 4, a flow cell 5 for measuring an electric potential, and the like. Further, the automatic analyzer 1 is provided with a plurality of sample containers 7 containing the sample 6 (only one is shown), and these sample containers 7 are transported to predetermined positions by a sample supply unit (not shown). .

A sample 6 and a diluent are dispensed into the dilution pot 2. A predetermined amount of the sample 6 is sucked from the sample container 7 by the sample probe 3 and conveyed to the dilution pot 2.
The sample probe 3 is connected to a transfer mechanism 8 and is moved by the transfer mechanism 8 in the horizontal and vertical directions. In addition, the sample probe 3 has a syringe 9 which is adjusted in advance to an appropriate suction / discharge speed by a syringe drive source 26.
Piped to. In addition, sample probe 3
Is maintained in a direction coinciding with the axial direction of the sample container 7 and the dilution pot 2 in order to surely and reliably enter a small-diameter blood collection tube, a urine collection tube, or the like.

The diluent is contained in the diluent container 10, and by utilizing the liquid supply means P ₁ such as a syringe and a pump,
A predetermined amount is supplied from the diluent discharge nozzle 11 to the dilution pot 2. A blade 12 is attached to the tip of the stirring rod 4. The stirring rod 4 is connected to the stirring motor 13 and is driven by the stirring motor 13 to rotate about the axis. Further, the stirring bar 4 is connected to the transfer mechanism 14 together with the stirring motor 13 and is moved by the transfer mechanism 14 in the horizontal direction and the vertical direction.

The dilution pot 2 is flown via a solenoid valve 15.
It is connected to cell 5. The diluted sample 16 in the dilution pot 2 is discharged from the bottom of the dilution pot 2 to the flow cell 5,
The flow cell 5 measures the potential of the components of the diluted sample 16. The output signal of the flow cell 5 is sent to the arithmetic unit 17, and the arithmetic unit 1
7 calculates the electrolyte concentration of the diluted sample 16. Here, as the flow cell 5, one using an ion selective electrode is known.

Reference numeral 18 in FIG. 6 is a cleaning liquid discharge nozzle, and reference numeral 19 is a cleaning liquid container. Washing container 19
When measuring a plurality of types of samples, a sufficient amount of the cleaning liquid therein is supplied to the dilution pot 2 and the flow cell 5 by the liquid supply means P ₂ such as a syringe or a pump after the measurement of each sample.

Each component of the automatic analyzer 1 described above operates in the following procedure. First, the sample probe 3 is transferred to a predetermined sample container 7 and enters the sample container 7, and a predetermined amount of sample 6 is sucked into the sample probe 3. Further, the sample probe 3 moves up and moves horizontally, and the dilution pot 2
Then, the sample 6 is discharged to the dilution pot 2. And
The sample probe 3 is retracted from the dilution pot 2. After that, a predetermined amount of the diluting liquid is discharged to the diluting pot 2 to dilute the sample 6.

The stirring rod 4 horizontally moves to reach the upper portion of the dilution pot 2, and then descends to enter the dilution pot 2. Further, the blade portion 12 of the stirring rod 4 is inserted into the diluted sample 16, and the stirring rod 4 rotates together with the blade portion 12.
The diluted sample 16 is agitated as the blade 12 rotates. Then, after the stirring is completed, the stirring rod 4 moves upward and horizontally, and retreats to the original position. Here, FIG. 6 shows a state of the diluted sample 16 at the time of stirring.

The stirred diluted sample 16 is sucked into the flow cell 5, and the flow cell 5 measures the electrolyte concentration of the diluted sample 16. Such an operation is repeated, and a predetermined analysis is continuously performed on a large number of samples.

In addition to the analyzer 1 in which the diluting pot 2 is fixed and the stirring rod 4 is moved, there is also a type in which the diluting pot 2 is moved to a sample discharging position, a diluting liquid discharging position, and a stirring position. It

[0011]

As described above, in the conventional automatic analyzer 1 as described above, the sample probe 3 and the stirring rod 4 are put together in the dilution pot 2 due to the size limitation of the dilution pot 2. Therefore, the mechanism 14 for transferring the stirring rod 4 is required and the entire apparatus is large. Furthermore, since the number of parts is large and the configuration is complicated, maintenance is troublesome and the cost is high. An object of the present invention is to provide an automatic analyzer having a simple structure and a small size.

[0012]

In order to achieve the above object, the present invention provides a diluting pot containing a dilute sample consisting of a sample and a diluting liquid, and a sample ejecting means for ejecting the sample into the diluting pot. And an automatic analyzer equipped with a stirring rod that is inserted into the dilution pot and stirs the diluted sample, the stirring rod is fixed in a fixed position while being inserted into the dilution pot, and the stirring rod is inclined with respect to the dilution pot. Especially. By doing so, the present invention aims to simplify the configuration and to downsize the automatic analyzer.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS. The same parts as those described in the section of the related art are designated by the same reference numerals, and the description thereof will be omitted. Furthermore, in the following examples, a case where a large number of samples are measured using one dilution pot will be described. However, even when a plurality of dilution pots are used for increasing the number of samples and for a standard sample or a special sample, Since the same explanation can be made, the explanation is omitted.

FIG. 1 shows an embodiment of the present invention, in which reference numeral 31 is an automatic analyzer. The automatic analyzer 31 includes a dilution pot 2, a sample probe (sample discharging means) 3, a stirring rod 4, a flow cell 5 for measuring an electric potential, and the like.

Of these, the dilution pot 2 is formed into a test tube shape, and the upper portion of the dilution pot 2 is opened in a perfect circle shape, and the bottom portion is formed into a hemispherical shape. further,
The dilution pot 2 is fixed at a fixed position of the automatic analyzer 31. In order to hold the dilution pot 2 at a fixed position, various general means and structures can be adopted.

A discharge pipe 20 is provided at the bottom of the dilution pot 2, and a discharge pipe 20 is provided at the center of the bottom of the dilution pot 2.
A discharge hole 21 that communicates with is opened. The discharge pipe 20 is connected to the flow cell 5.

The stirring rod 4 has a blade portion 12 at the tip thereof, and the blade portion 12 is provided with four rectangular blades 12a. The blades 12a are arranged at substantially equal intervals and project substantially vertically in the radial direction of the stirring rod 4. Further, the stirring rod 4 is connected to the stirring motor 13, and is rotated by the stirring motor 13 together with the blade portion 12 about the axis.

The stirring rod 4 is held together with the stirring motor 13 by the stirring rod holding portion 32.
The tip of the is inserted into the dilution pot 2. The stirring rod holder 32 is fixed at a fixed position of the automatic analyzer 1. Therefore, the positions of the stirring motor 13 and the stirring rod 4 are constant. Furthermore, the stirring rod 4 is oriented obliquely by the stirring rod holding portion 32, and is inclined at a predetermined angle θ ₁ with respect to the axis 2a of the dilution pot 2 as shown in FIG. The blade 12 is always located in the dilution pot 2. Here, the effective range of θ ₁ is 10 ° to 30 °
And is preferably 15 ° to 20 ° in terms of design or operation.

The stirring rod holding portion 32 is only required to be able to hold the stirring rod 4 in a tilted manner, and various general stirring rod holding portions 32 can be adopted. The sample probe 3 is connected to the transfer mechanism 8 and is arbitrarily moved in the horizontal direction and the vertical direction by the transfer mechanism 8 as shown by arrows A and B. Then, the sample probe 3 is connected to the sample container 7
And the dilution pot 2 is reciprocated. Here, various general mechanisms can be adopted as the transfer mechanism 8.

Further, the sample probe 3 is the dilution pot 2
When stopped above, the orientation of the sample probe 3 becomes parallel to the axis 2a of the dilution pot 2. Further, the stop position of the sample probe 3 on the dilution pot 2 is set so that the tip of the sample probe 3 faces the blade portion 12 of the stirring rod 4, as shown in FIG. That is, when the sample probe 3 is positioned on the dilution pot 2, the blade portion 12 is interposed between the tip of the sample probe 3 and the discharge hole 18 opened at the bottom of the dilution pot 2. Further, the sample probe 3 is biased to a position on the opposite side of the stirring rod 4 with respect to the axis 2a of the dilution pot 2 and at a position where it can freely enter the dilution pot 2. Further, the horizontal clearance C between the sample probe 3 and the stirring rod 4 changes gradually as it goes upward.

The operations of the transfer mechanism drive source 24, the syringe drive source 26, the liquid supply means P ₁ and P ₂ , and the stirring motor 13 are controlled by the control unit 27. Next, the operation of the above-mentioned automatic analyzer 21 will be described.

First, the sample probe 3 is transferred to the sample container 7, the piston 9a of the syringe 9 is pulled down, and a predetermined amount of the sample 6 is sucked into the sample probe 3. Further, the sample probe 3 is transferred to the dilution pot 2, reaches a predetermined position above the dilution pot 2, and then descends toward the dilution pot 2. Where sample pro
The degree of invasion of the bulge 3 into the dilution pot 2 is such a low position that the water discharge portion does not adhere to the wall surface or the stirring rod at the time of discharge, and there is no splashing from the bottom of the dilution pot 2, the blades 12 or the water surface due to discharge. The range is set so that the position is high enough to be suppressed appropriately. Then, the piston 9 a of the syringe 9 is pushed up, and the sample in the sample probe 3 is discharged to the dilution pot 2.

At this time, the electromagnetic valve 15 located between the dilution pot 2 and the flow cell 5 is closed, so that the sample is accumulated in the dilution pot 2. Also, sample probe 3
The sample discharged from the sample is, as indicated by an arrow D in FIG.
Once it hits the blade portion 12, it accumulates at the bottom of the dilution pot 2.

Thereafter, the diluent is discharged from the diluent discharge nozzle 11 to the dilution pot 2, and the sample and the diluent are mixed in the dilution pot 2. The stirring motor 13 is driven, the stirring rod 4 rotates, and the blade portion 12 stirs the diluted sample 16.
Since the blade 12 is always in the dilution pot 2, the blade 12 is immersed in the diluted sample 16 as the sample and the diluent are discharged. Here, the height of the blade 12 is
Of the diluted sample 16 in which the whole of the
It is set to be positioned lower than a.

After sufficient stirring is performed, the stirring motor 1
3 stops. Further, the solenoid valve 15 is opened and the diluted sample 1
6 flows through the discharge pipe 20 and passes through the flow cell 5. The flow cell 5 measures the potential of a predetermined component of the diluted sample 16, and the output signal of the flow cell 5 is sent to the arithmetic unit 17 to obtain the concentration of each component, and then display means (not shown) or recording means. The measurement result is displayed or recorded by the means.

After the diluted sample 16 is discharged from the dilution pot 2, the cleaning liquid discharge nozzle 18 discharges the cleaning liquid to the dilution pot 2, and the dilution pot 2 is a contaminant for continuous measurement.
Washed to prevent rusting. At this time, in order to promote the cleaning action in the dilution pot 2, the electromagnetic valve 15 is closed, the stirring rod 4 is rotated with the cleaning liquid contained in the dilution pot 2 in a sufficient amount, and then the electromagnetic valve 15 is again rotated. May be opened. After the cleaning, the unnecessary cleaning liquid is discharged through the discharge pipe 20.

In the automatic analyzer 31 as described above, since the stirring rod 4 is fixed at a fixed position, the sample 6
It is not necessary to retract the stirring rod 4 prior to the discharge of. For this reason, a transfer mechanism for the stirring rod 4 is not required, and it is possible to simplify the configuration and downsize the automatic analyzer 31.
Further, since the transfer mechanism for the stirring rod 4 can be omitted, the cost is reduced. Further, since it is not necessary to spend time to move the stirring rod 4, the working time can be shortened and the analysis processing can be sped up.

When the stirring rod 4 is simply fixed at a fixed position, in order to avoid the interference of the sample probe 3 with the stirring motor 13 and the blades 12,
It is necessary to secure a sufficiently large clearance between the brush 3 and the stirring rod 4. Furthermore, to prevent the sample discharged from the sample probe 3 from spilling out of the dilution pot 2,
The opening diameter of the dilution pot 2 must be set sufficiently large. When the diluting pot 2 is enlarged, it becomes necessary to increase the amount of sample dispensed, which makes it difficult to analyze a small amount of sample.

However, by tilting the stirring rod 4 with respect to the dilution pot 2 as in this embodiment, the clearance C between the sample probe 3 and the stirring rod 4 can be easily secured. For this reason, sample probe 3 and stirring motor 1
3 and the stirring rod 4 can be prevented from interfering with each other, and there is no need to upsize the dilution pot 2 or increase the amount of sample dispensed.

Further, since the blade portion 12 of the stirring rod 4 is interposed between the discharge hole 21 of the dilution pot 2 and the sample probe 3, the sample discharged from the sample probe 3 is a blade portion 12. When it hits, the momentum of discharge weakens. Therefore, it is possible to prevent the ejected sample from directly entering the discharge pipe 20 due to the force of ejection. Therefore, the separation of the sample and the diluent can be prevented, the two solutions can be easily mixed, and highly reliable and stable analysis results can be obtained.

Further, since the sample probe 3 is discharged at a position where it is biased as shown in FIG. 2, it is possible to effectively prevent the sample from adhering to the handle portion of the stirring rod 4.
The dilution accuracy is improved and contamination between samples can be prevented.

On the other hand, if the sample probe 3 is tilted, the sample is likely to adhere to the upper part of the stirring rod 4 or the dilution pot 2, the diluting accuracy is deteriorated, and contamination between samples is caused, which is not preferable.

The present invention is not limited to the above-described embodiments, but can be variously modified without departing from the scope of the invention. For example, in the present embodiment, the sample probe 3 and the diluent discharge nozzle 11 are independent, but the present invention is also applied to an analyzer in which one nozzle is used for both sample discharge and diluent discharge. It is possible.

For example, as shown in FIG. 4, the dilution pot 41
Of the opening 42 of the horizontal plane 45 ° to 60 °, for example.
If the diluting pot 41 is provided with the inclined surface 43 by inclining by (= θ ₃ ), and the diluting pot 41 is provided with the inclined surface 43, the stirring rod 4 is prevented from being restricted by a larger angle θ ₃ (> θ ₃
Can be tilted with ₁ ). Therefore, it is possible to easily secure a large clearance C and increase the degree of freedom in design. In particular, sample probe 3
4, there is no difficulty in designing when entering from the center of the dilution pot 2 or when arranging various nozzles or the like between the sample probe 3 and the stirring rod 4. It is preferable in that it is possible to effectively avoid adhesion or contamination to the handle portion of No. 4. Further, since the opening 42 is expanded to the outside, the sample, the diluting liquid, the cleaning liquid, etc. can be reliably stored in the diluting pot 41. Further, it is possible to prevent spillage of these liquids and prevent the surrounding of the dilution pot 41 from being soiled.

Further, as shown in FIG. 5, the dilution pot 51
Only a part of the opening 52 may be expanded outward. In addition,
In FIG. 5, the inclination angle of the inclined surface 53 and the inclination angle (θ ₃ ′) of the stirring rod 4 are substantially the same, but in order to avoid vibration, the inclined surface 53 and the stirring rod 4 are separated by a certain distance. I am letting you. With the configuration shown in FIG. 5, while the expansion of the opening 52 of the diluting pot 51 is minimized, the same function and effect as in FIG. 4 can be obtained, and even when the ejection or stirring force is strong, It is possible to effectively prevent the splashing due to the bounce of the water, and the dilution accuracy is maintained stable.

Further, the control unit 27, depending on the measurement object,
The liquid supply means P ₁ and the syringe drive source 26 may be controlled so as to change the ratio between the diluent and the sample amount. In this case, the stirring rod 4 is always waiting in the dilution pot 2 even when the time or the time of invasion of the sample probe 3 into the dilution pot 2 is changed. It has an advantageous aspect in that the control system can be simplified because only the stirring operation can be performed.

[0037]

As described above, according to the present invention, a diluting pot containing a dilute sample consisting of a sample and a diluting liquid, a sample ejecting means for ejecting the sample into the diluting pot, and a diluting pot inserted into the diluting pot are provided. In an automatic analyzer equipped with a stirring rod for stirring a diluted sample, the stirring rod is fixed in a fixed position while being inserted into the dilution pot, and the stirring rod is inclined with respect to the dilution pot. Therefore, the present invention
This has the effect of simplifying the configuration and reducing the size of the automatic analyzer.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing a main part of an automatic analyzer according to an embodiment of the present invention.

FIG. 2 is an explanatory view showing the inclination of a stirring rod.

FIG. 3 is an explanatory view showing a positional relationship among a sample probe, a stirring rod and a dilution pot.

FIG. 4 is an explanatory diagram showing a modified example.

FIG. 5 is an explanatory diagram showing another modification.

FIG. 6 is a configuration diagram showing a conventional example.

[Explanation of symbols]

31 ... Automatic analyzer, 2 ... Diluting pot, 3 ... Sample probe (sample discharging means), 4 ... Stirring bar, 16 ... Diluted sample, 32 ... Stirring bar holding section.

Claims (1)

[Claims] 1. A dilution pot for accommodating a diluted sample consisting of a sample and a diluting solution, a sample ejection means for ejecting the sample to the dilution pot, and an agitation for agitating the diluted sample inserted in the dilution pot. An automatic analyzer equipped with a rod, wherein the stirring rod is fixed in a fixed position while being inserted in the dilution pot, and the stirring rod is inclined with respect to the dilution pot.