JPS63121755A - Automatic chemical analysis instrument - Google Patents

Abstract

PURPOSE:To permit pure supply of an additive for cleaning up with simple constitution by using a nozzle for dispensing a reagent commonly as a nozzle for supplying an additive to constant temp. water in a thermostatic chamber. CONSTITUTION:Plural reaction cells 3a, 3b, 3c... are housed in the constant temp. water 2 in the thermostatic chamber 1. The constant temp. water 2 is required to be cleaned at every specified time to prevent the generations of contaminations, fur, etc. The additive is sucked by the nozzle 6 for supplying the additive and is supplied to the constant temp. water in the thermostatic chamber in the case of disposing an additive housing tray 8 adjacently to the thermostatic chamber 1 and supplying the additive for cleaning into the thermostatic chamber. The additive is, therefore, surely supplied with the simple constitution without requiring the pump and nozzle to be exclusively used for the additive.

Description

[Detailed Description of the Invention] [Objective of the Invention] (Industrial Application Field) The present invention is an automated chemical analysis method that measures the absorbance inside a reaction cell while the reaction cell is placed in a constant temperature bath and maintained at a predetermined temperature. Regarding equipment.

(Prior art) Human serum, etc. is used as a sample and a desired reagent is added to cause a chemical reaction, and the state of this reaction is optically measured to obtain photometric data for diagnosis. An automatic chemical analyzer is known. When measuring the reaction state inside a reaction cell using such an automatic chemical analyzer, the reaction cell containing the sample and reagent is placed in a constant temperature bath and maintained at a constant temperature to ensure normal reaction. This is taken into consideration.

In this case, the constant-temperature water in the constant-temperature bath becomes contaminated over time, causing limescale and the like to form in an undesirable state. To prevent this, means are provided to purify the constant-temperature water at regular intervals.

One way to do this is to install a dedicated pump and nozzle around the constant temperature tank, and use these to supply purifying additives to the constant temperature water in the constant temperature tank at regular intervals. Another method is to dilute the purifying additive in advance with pure water to a specified concentration, and then supply this diluted solution into the thermostatic chamber using a dedicated pump.

(Problems to be Solved by the Invention) However, either method requires a dedicated pump or nozzle, which increases costs and requires space for installing these. In addition, obtaining a diluted solution with a predetermined concentration requires a lot of effort and effort, resulting in a large burden. It becomes difficult to determine whether or not the purifying additive has been reliably supplied.

The present invention has been made in response to the above-mentioned problems.
The object of the present invention is to provide an automatic chemical analyzer that can reliably supply septic tank additives with a simple configuration.

[Structure of the Invention] (Means for Solving the Problems) In order to solve the above object, the present invention includes a tray for containing additives arranged adjacent to a constant temperature bath, and a tray for sucking additives from this tray. It is characterized by being equipped with a nozzle for supplying additives into the constant temperature bath.

(Function) When it is desired to supply the purifying additive into the thermostatic chamber, the additive is supplied by suctioning the additive from within the additive storage tray using the additive supply nozzle.

This additive supply nozzle can also be used as a reagent dispensing nozzle used when dispensing a reagent to a reaction cell.

(Embodiment) Fig. 1 is a cross-sectional perspective view showing an automatic chemical analyzer according to an embodiment of the present invention. An annular constant temperature bath 1 is filled with constant temperature water 2, and this constant temperature water 2 is kept at a constant humidity of, for example, 37°C. It is set to be maintained. Further, a plurality of reaction cells 3a, 3b, 3c, . A plurality of reaction cells 3a, 3b, 3
c.

... are integrally held by a holder 4, and are sequentially moved in the direction of the arrow by rotating this holder 4 by a drive source (not shown). The holder 4 performs a rotational movement in a constant cycle through a stop period. For example, by performing a rotational movement of 1 rotation + 1 pitch in one cycle, each reaction cell can be sequentially moved forward by 1 pitch in each cycle. can. A sample dispensing nozzle 5 is arranged at a predetermined position in the thermostatic chamber 1, and by performing a rocking motion using an arm 5b and a shaft 5a as a fulcrum, a sample storage tray ( (not shown) and dispenses the desired sample.

An additive supply nozzle 6 is arranged at another predetermined position of the thermostatic chamber 1, and swings around a shaft 6a via an arm 6b. A tray 8 for containing additives is arranged at another predetermined position of the thermostatic oven 1, and the thermostatic oven 1 is contained in this tray 8.
A purification additive 9 is prepared for purifying the constant temperature water 2 inside.

A protrusion 1a is provided in a portion of the constant temperature bath 1 opposite to the additive storage tray 8, and continues into the constant temperature bath 1. Therefore, as the additive supply nozzle 6 performs a swinging motion, the purifying additive 9 sucked from the tray 8 is supplied to the constant temperature water 2 in the constant temperature bath 1 from the protrusion 1a.

The additive supply nozzle 6 also serves as a reagent dispensing nozzle. When the nozzle 6 is used for dispensing a reagent, the nozzle 6 performs a rocking motion to dispense a desired amount of suction from a reagent storage tray (not shown) into a reaction cell that has moved to an opposing position.

A photometric system 7 for optically measuring the chemical reaction state between the sample and the reagent in the reaction cell is disposed in the middle of the thermostatic chamber 1 . The photometry system 7 includes a lamp 7a provided on the inner circumference side of the thermostatic chamber 1, a prism 7c provided on the outer circumference side, a diffraction grating 7d, a detector 70, and the like. While each reaction cell is in rotational movement, the optical path 7 from the lamp 7a to the prism 7G
The moment the light crosses b, the absorbance inside this reaction cell is detected by detector 7.
e to obtain photometric data.

In order to obtain accurate data with such photometry, the light emitted from the inner circumferential side of the thermostatic chamber 1 to the outer circumferential side must be
It is necessary that the constant temperature water 2 be unaffected by the state of the water, and for this purpose the constant temperature water 2 is supplied with purifying additives.

−〇　− Next, the operation of this embodiment will be explained.

With constant temperature water 2 being supplied into the constant temperature bath 1 by the pump, the additive 9 prepared in the additive storage tray 8 is sucked by the additive supply nozzle 6 (J in FIG. 2(a)). . Next, from this position, the nozzle 6 is moved clockwise around the shaft 6a in the direction of the arrow to move it to the position shown in FIG. The additive 9 is supplied to 1a. As a result, the constant temperature water 2 is mixed with additives and is purified. Thereafter, by such a method, the additive is supplied into the thermostatic chamber 1 at regular intervals.

Therefore, constant temperature water is always kept in a purified state,
It will not become contaminated over time and will be in a desirable state with no limescale or the like. Therefore, when performing photometry, the optical path is less affected by the constant temperature water 2, so accurate photometry data can be obtained.

When the nozzle 6 is used for reagent dispensing, a desired reagent is sucked from a reagent storage tray and dispensed into a corresponding reaction cell, for example 3a, as shown in FIG.

The nozzle 6 can be easily used for additive supply or reagent dispensing by operating a control mechanism (not shown).

Not only one purifying additive tray but also a plurality of purifying additive trays can be arranged to prepare different additives for each tray. Alternatively, one tray may be partitioned to prepare a plurality of types of additives.

According to such an embodiment of the present invention, there is no need to install a dedicated pump and nozzle to purify constant temperature water, and the originally provided reagent dispensing nozzle can be used for both purposes, thereby reducing stop-down. In addition, since the additive can be directly supplied to the constant temperature bath, there is no need to adjust the concentration. It is also possible to reliably determine whether or not the additive has been supplied.

The present invention can be applied not only to supplying additives to a constant temperature bath, but also as a detergent supply means for cleaning reaction cells and the like.

[Effects of the Invention] As described above, according to the present invention, the reagent dispensing nozzle that is originally provided also serves as an additive supply nozzle, so that purification additives can be reliably demanded with a simple configuration. can do.

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional perspective view showing an automatic chemical analyzer according to an embodiment of the present invention, FIGS. 2(a) and (b) are schematic diagrams showing the operation when additives are supplied by the device of the present invention, and FIG. 3 FIG. 2 is a schematic diagram showing the operation when dispensing a reagent using the device of the present invention. 1... Constant temperature bath, 1a... Protruding part, 2... Constant temperature water,
3.3a, 3b, 3G - Reaction cell, 4... Holder, 5... Sample dispensing nozzle, 6... Additive supply nozzle and reagent dispensing nozzle, 7... Photometry System, 8・
... Additive storage tray, 9... Additive.

Claims (2)

[Claims] (1) In an automatic chemical analyzer, a reaction cell into which samples and reagents are dispensed is placed in a thermostatic chamber, and a purifying additive is supplied into the thermostatic chamber at regular intervals. An automatic chemical analysis device comprising: a tray for containing additives; and an additive supply nozzle for sucking the additives from the tray and supplying the additives into a thermostatic chamber. (2) The automatic chemical analyzer according to claim 1, wherein the additive supply nozzle also serves as a reagent dispensing nozzle.