JPH06265555A - Automatic chemical analyzer - Google Patents

Abstract

PURPOSE:To enhance performance economically while facilitating the operation and to enhance reliability of analytical data while realizing downsizing by employing a unitized pure water producing section integrated with the analytical section and performing system control including the quantity, quality, etc., of original water and pure water. CONSTITUTION:The automatic chemical analyzer comprises a sample table 12, a reaction table 1, reagent tables 9, 10, a sampling section 11 for shifting a sample on the table 12 and a reagents on the tables 9, 10, a pure water producing section 18, a photometric section comprising a light source section 4 and a photometer 5, controllers 33, 38 for respective sections, and a data processing section D. The pure water producing section 18 contains a plurality of types of unitized water refining modules in an analyzer, while the control section determines combination of the plurality of types of water refining modules according to original water conditions and analytic conditions and performs quality control of pure water. The analyzer is controlled as an integral system.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic chemical analyzer, and provides a water supply system having a pure water purification function, which is automated, integrated and miniaturized according to the state of raw water and the purpose of pure water required. The present invention relates to an automatic chemical analysis device provided.

[0002]

2. Description of the Related Art The wet analysis method, which is one of the conventional analysis techniques, is excellent in reproducibility and quantification accuracy because the analysis conditions such as the temperature of the analysis reaction and the humidity of the reaction substance can be accurately defined. The device, the so-called automatic chemical analysis device,
It is widely used in hospitals and clinical laboratories as an indeterminate device for diagnosis and early detection of diseases.

The pure water used in these automatic chemical analyzers has many uses such as for liquid transfer for quantitative transfer of samples and reagents, cleaning of each part of the device such as a nozzle, and water supply to a reaction tank. is there. The pure water described above should be pure with little particles and dust in order not to damage the pipettor, pump and on-off valve used in the piping system. Further, the pure water used in the sampling pipettor, nozzle, etc. during the analysis operation must be pure without including dust and the like from the viewpoint of the function of the device. For example, when detecting the liquid level of a reagent and the nozzle detects a change in capacitance,
Sufficient specific resistance of pure water is required. In particular, strict control is required regarding biological contamination such as live bacteria and mold.

However, in the conventional automatic chemical analyzer, the pure water production unit for purifying the pure water in the water supply system is
Using off-the-shelf commercial products, it is built separately from the main body of the automatic chemical analysis device and is constructed in a large size.From the system viewpoint including the entire automatic chemical analysis device, for example, water quality, pressure,
Control of pure water such as water leakage is not considered. Further, there is a drawback in that due to the condition of the connection pipe between the pure water production unit and the main body of the automatic chemical analyzer, no consideration is given to the generation of bacteria such as live bacteria, the generation of bubbles, and the change in water quality in the connection pipe unit.

[0005]

In the above-mentioned conventional wet analysis method, pure water for liquid transfer for quantitatively transferring a required sample or reagent, cleaning of each part of the device such as a nozzle, and water supply to a reaction tank are used. The pure water production unit that purifies pure water is not only constructed separately from the main body of the automatic chemical analyzer as described above, but is also constructed in a larger size, and especially the operation of each unit of the automatic chemical analyzer is controlled during purification. It does not supply the necessary signals from the data processing unit that calculates the measurement data to the controller, nor does it supply the signals from the pure water production unit to the automatic chemical analyzer, and they are independent of each other. And it was working.

[0006] Therefore, the electrical conductivity is reduced due to a large consumption of raw water, a decrease in purity of pure water, generation of various bacteria, clogging of a flow path such as mixing of fine particles, dirt, etc., and a scale component such as Ca, Mg or Na. Due to the influence of the residual of the above, the analytical data became abnormal, and sufficient electric conductivity could not be obtained. There are problems such as erroneous recognition of a sample due to malfunction of the liquid level detection electrical system that is directly caused by these water qualities.

The present invention has been made to solve the above-mentioned problems of the prior art. An automatic chemical analyzer is constructed and used by integrating its main body and a pure water production unit into a compact unit. By designing a system that includes the amount of pure water used and the water quality, etc., the analytical performance and instrument functions are improved, making the entire system economical, easy to use, and highly reliable in analysis data. It is intended to provide a chemical analyzer.

[0008]

In order to achieve the above object, the structure of an automatic chemical analyzer according to an embodiment of the present invention is such that a sample table holding a sample container and a reaction container row are held. A reaction table having a reaction line to be transferred, a reagent table holding a reagent, a part of a sample in a sample container on the sample table and the reagent table.
Sampling part for inhaling a part of the reagent in the reagent container of the bull and discharging and transferring it to the reaction container, a pure water production part for supplying pure water to each part, and a sample processed in the reaction container A photometric section for optically measuring the light, a controller for controlling the operation of each section, and a data connected to the controller for arithmetically processing the measurement data from the photometric section.
The pure water production section is composed of a plurality of types of pure water purification modules and unitized, and is stored in the housing of this automatic chemical analyzer to monitor the quality of pure water.
Control means is provided for controlling and determining the combined configuration of the plurality of types of pure water purification modules according to raw water conditions and analysis conditions, and controlling the automatic chemical analysis device as an integrated system. .

That is, the constitution of various pure water purification units that are modularized according to the hardness components of Ca and Mg which are components of raw water such as tap water is determined. For example, a pure water production unit consisting of a combination of an ion exchange resin unit and a reverse osmosis membrane unit is housed in the same housing as the main body of the automatic chemical analyzer, and the functions are integrated to control the pure water production unit as an integrated system. This is performed by a controller that controls the operation of each part of the automatic chemical analyzer and a data processing unit that performs arithmetic processing on the measurement data connected to the controller.

[0010]

The function of each of the above technical means is as follows.
According to the configuration of the present invention, the pure water producing unit determines the combination of a plurality of pure water purification modules according to the purpose, and the pure chemicals manufacturing unit is housed in the same housing as the main body of the automatic chemical analysis device.
It is possible to construct a miniaturized automatic chemical analyzer.
In addition, the control unit consisting of the controller and the data processing unit controls the raw water and the pure water according to the use of the automatic chemical analyzer as an integrated system, so that the pure water satisfying both the quality and the quantity can be obtained. Can be obtained economically.

More specifically, the pressure and flow rate of the raw water sent from the water supply pump, for example, MPa and 1 / h are specified.
When the raw water sent from the water pump passes through the pure water purification module unit, for example, the specific resistance and MΩ-cm are increased due to the adsorption action of the anion and cation ion exchange resins and the negative ions and positive ions contained in the raw water. To rise. Also,
The pure water from which fine particles have been removed is obtained by the pressure difference due to the reverse osmosis membrane of the reverse osmosis membrane module.

Further, the pure water producing unit is controlled as a system in which the hierarchical system of the controller and the data processing unit is integrated by the signals from the water quality meter, the pressure switch and the flow passage opening / closing valve. Since it was made possible, the raw water components,
The amount of raw water used, the quality of pure water obtained, and the pressure are controlled,
This automatic chemical analyzer operates optimally.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS. 1 is a schematic explanatory view including a partial block diagram of an automatic chemical analyzer according to an embodiment of the present invention, FIG.
2 is a block diagram showing the configuration of a pure water purification unit module in the automatic chemical analyzer according to the embodiment of FIG. 1, FIG.
FIG. 2A is a front view and a side view of the automatic chemical analyzer according to the embodiment of FIG.

First, the entire automatic chemical analyzer according to one embodiment of the present invention will be described. In FIG. 1, an automatic chemical analysis apparatus includes an analysis unit U for automatically measuring a plurality of samples, for example, 400 / 1h samples, and a data processing unit for controlling the analysis unit U and printing measurement data. And D. The two are connected by a connection cable 40 for supplying power and transmitting signals.

The analysis unit U comprises a circular sample table 12 on which a sample container 16 is placed, and a circular reaction table which holds the reaction container 3 near the sample table 12. -Table 1, a first reagent table 9 and a second reagent table 10 in which a reagent container 17 is provided adjacent to both the tables, and a sample and a reagent of each of the tables. Sampling parts 11 ₁ , 1 for discharging and transferring to the reaction container 3
1 ₂ , 11 ₃ and the sun bling portion 11 ₁ , 11 ₂ , 11
₃ , a pipette unit 6 for supporting the operation of 3, a photometric unit consisting of a light source unit 4 for measuring a sample subjected to the reaction treatment in the reaction vessel 3 and a photometer 5, and pure water supplied to each unit to control the controller 3
3, a pure water producing unit 18, an auxiliary device such as a tank 14 and a water supply pump 15 for supporting the water supplying operation of the pure water producing unit 18, and a controller 3 for controlling the operation of each of these units.
8 and pipes and wirings connecting the above-mentioned respective parts.

On the sample table 12, a sample container 16 in which a fixed amount of serum for each patient separated from the whole blood by centrifugation or the like is injected at the time of sample measurement is placed in a circular shape. 12 is rotated by a drive device (not shown).

In the reaction table 1, reaction vessels 3 for processing a reaction between a sample and a reagent are arranged in a line in a circle and held by a reaction line 2. The reaction table 1 is rotated by a driving device (not shown). The reaction container 3 is kept at a constant temperature by a thermostat (not shown) provided in the reaction table 1.

Various reagents corresponding to the analysis of the sample are:
The first reagent table 9 and the second reagent table 10 are provided in the reagent containers 17a and 17b, respectively, and are kept at a constant temperature by a thermostat (not shown).

The sampling unit for transferring the sample and the reagent is 1
There are three types, 1 ₁ , 11 ₂ and 11 ₃ , and they are connected to the pipetter section 6. The pipette unit 6 has a syringe structure (not shown). Since the sampling unit 11 ₁ and the sampling units 11 ₂ and 11 ₃ have exactly the same structure, only the sampling unit 11 ₁ will be described and the other sampling units 11 ₂ and 11 ₃ will be omitted.

The sampling unit 11 ₁ has an arm 11a having a hollow portion inside and a nozzle 8a at its tip.
And a hollow shaft tube 8r, the arm 11a rotates about the hollow shaft tube 8r, and the nozzle 8a also rotates accordingly. Further, the nozzle 8a is also moved up and down by moving the hollow shaft tube 8r up and down. The nozzle 8a, the arm 11a, and the hollow shaft tube 8r are connected to the pipette portion 6 and the pure water feed pump 1 via the pipette portion 6.
5 is connected to the pipe.

At a predetermined position just below the nozzle 8a,
A washing tank 7 having an overflow function of a fixed volume is provided, and the tip of the nozzle 8a is immersed in the washing tank 7 by the above-described lifting movement, and the inner surface and outer wall of the nozzle 8a are provided. And wash. Carry between samples from this washing
Cross contamination caused by the bar is prevented.

The sampling unit 11 _1, A - by the vertical movement of the shaft tube 8r rotary motion and hollow arm 11a, the sample tape - the nozzle 8a within predetermined the sample container 16 placed on the bull The sample in the sample container 16 is inserted and a predetermined amount is sucked from the nozzle 8a by the reciprocating motion of the syringe piston of the pipetter part 6. Arm 11a again
And the pure water from the pure water producing section 18 through the water supply pump 15 into the predetermined reaction container 3 on the reaction table 1 and the sample. Is discharged.

[0023] In the same manner, the sampling unit 11 ₂ is the first reagent Te - from the reagent container 17a on the table 9, the sampling unit 11 ₃ and the second reagent Te - reagent containers 17 on the table 10
A desired amount of each desired reagent is discharged into the reaction container 3 from b. In this way, the predetermined sample and reagent are injected into the reaction container 3 together with pure water from the pure water producing unit 18.

The reaction container 3 in which a predetermined sample and reagent are injected together with pure water is kept at a constant temperature by a constant temperature bath, and the reaction is completed after a lapse of a predetermined time. The reaction container 3 in which the reaction has been completed is measured by the light source unit 4 and the photometer 5 as it is to obtain a measured value.

The controller 38 controls the operation of each of the above-mentioned parts and is connected to the data processing device D so as to be connected to the data processing device D.
In addition to receiving a control command from the water treatment device D, it is also connected to the pure water purification controller 33 of the pure water producing unit 18 to issue a control command.

The data processing section D is connected to the controller 38 of the analysis unit U by a connection cable 40 for supplying power and transmitting signals, and the controller 38 is connected to the controller 38.
Controller 33 of the pure water producing unit 18 through the controller 38.
Are connected together and together control the entire analysis unit U. The data processing unit D is provided with a random access function for analyzing only the designated items of the sample and outputting the result, an interrupt measurement of an urgent sample, an automatic start-up function that operates unattended, and the like. Light source unit 4 and photometer 5
The measured values obtained by and are output as final data for disease diagnosis.

Next, the pure water producing section 18 will be described.
The pure water producing unit 18 is disposed in the analysis unit U device, and purifies the pure water for liquid feeding and for cleaning. In FIG. 1, the pure water producing unit 18 includes a water source 20, for example, a tap water pipe, and a flow path opening / closing valve 21 for passing and blocking water supply.
And fibrous filter 1 for removing red rust and particles in raw water
9, a high pressure pump 23 connected to the fibrous filter 19 for supplying pressurized water, a reverse osmosis membrane module 27 connected to the water supply side of the high pressure pump 23 for removing residual chlorine by the reverse osmosis principle, The reverse osmosis membrane module 27 is composed of an ion exchange resin module 36 having a deionizing action, a pure water purification controller 33, and the like.

Further, the ion exchange resin module 36
The water supply port is connected to a separate water storage tank 14 having the float switch 13 by piping, and then connected to the water supply pump 15 and the pipetter section 6.

In each part of the above components, a pressure switch 22 is provided at the outlet of the fibrous filter 19, a pressure monitor 24 is provided at the inlet of the reverse osmosis membrane module 27, and a pressure switch 30 and a water quality meter 28 are provided at the outlet. , A pressure monitor 29 at the inlet of the ion exchange resin module 36, and a water quality meter 3 at the outlet.
2 etc. are provided.

An intermediate valve of the reverse osmosis membrane module 27 is provided with a squeezing valve 26 for adjusting the pressure of the pressurized tap water and an opening / closing valve 25 for flushing cleaning, and the other end of the opening / closing valve 25. A waste water port 31 is provided in the.

The deionized water purification controller 33 is connected to the above-mentioned components of the deionized water producing section 18 by wiring and is controlled, and is also connected to the controller 38. Further, the deionized water purification controller 33 is connected to the controller 38 via the controller 38. A data processing device D is also connected to form a so-called hierarchical system.

Next, the pure water producing process of the pure water producing unit 18 will be described. A case where the pure water purification module is composed of a reverse osmosis membrane module 27 and an ion exchange resin module 36 as shown in FIG. 1 will be described. The flow path opening / closing valve 21 for opening / closing the raw water flow path is opened / closed at a timing at which pure water is always required by the float switch 13 provided in the water storage tank 14. The tap water that has passed through the passage opening / closing valve 21 is passed through the fibrous filter 19 to remove red rust, particles, etc. contained in the raw water.

Next, the high-pressure pump 23 feeds water to the reverse osmosis membrane module 27 in a pressurized state, for example, a pressure of 0.7 MPa. In the reverse osmosis membrane module 27, residual chlorine and evaporation residue are removed by the principle of reverse osmosis to obtain pure water.
Further, this pure water is deionized by the ion exchange resin module 36 and has a high specific resistance, for example, 1 MΩcm to 1
It becomes pure water of 8 MΩcm and is stored in the water storage tank 14.

The quality of the pure water stored in the tank 14 depends largely on the pressure and flow rate supplied to the modules 27 and 36 for purifying the pure water. For this reason,
The pressure monitor 24 measures the inlet pressure of the reverse osmosis membrane module 27, and the pressure monitor 29 measures the inlet pressure of the ion exchange resin module 36, which are input to the pure water purification controller 33. The pressure and the flow rate are controlled by the pure water purification controller 33.

The pressure switch 22 detects pressure drop due to clogging of the fibrous filter 19, and the pressure switch 30 is provided at the outlet of the reverse osmosis membrane module 27 to detect abnormal pressurization. Each prevents malfunction.

For the specific resistance value of pure water, the water quality meter 28 measures the specific resistance value of pure water obtained by the reverse osmosis membrane module 27, and the water quality meter 32 uses the ion exchange resin module. The specific resistance values of the pure water obtained by the measuring unit 36 are measured and input to the pure water purification controller 33 and controlled respectively.

The flow rate of the tap water is adjusted by the quality value of the pure water, and the reverse osmosis membrane module 27 is withdrawn from the squeezing valve 26 at the intermediate stage.
The pressure of the pressurized tap water to 7 is adjusted to adjust the flow rate. The flushing cleaning of the reverse osmosis membrane module 27 is performed by the opening / closing valve 25.

The pure water purifying controller 33 includes the squeezing valve 26, the opening / closing valve 25, and the pressure switches 2.
2, 24, 29, 30, each of the water quality meters 28, 32, and the high-pressure pump 23, which receives an input signal from them and outputs a necessary output signal to the controller 38, which controls the analysis unit U. The data is sent to a hierarchical system constituted by the data processing section D and the whole automatic chemical analyzer is controlled.

As described above, with the entire system as one system, the pressure of the tap water in the pure water producing section 18 and the specific resistance value of pure water obtained by passing through the pure water purification module are used as the pure water purification control.
Feedback control is performed by the controller 33, the controller 38, and the data processing unit D, so that pure water of a predetermined water quality can be reliably obtained.

Next, the pure water purification module of the pure water producing section 18
The unitization by the rule is explained. 2 (a), (b),
(C) and (d) are block diagrams showing a configuration of a unit of a pure water purification module in an automatic chemical analyzer according to an embodiment of the present invention. In the figure, the same symbols as those in FIG. 1 are the same parts, and thus detailed description thereof will be omitted.

In FIG. 2, 37 is an ion exchange fiber module using a fiber having an ion exchange function, and 42 is
It is an electrodialysis module utilizing the electrolyte dialysis action of a membrane. The configurations of these four types of pure water purification modules are respectively housed in a housing to form four types of unitized pure water producing sections 18.

The unit shown in FIG. 2A is constructed by connecting a reverse osmosis membrane module 27 and an ion exchange resin module 36. The unit shown in FIG. 2B is composed of an ion exchange resin module 36, an ion exchange fiber module 37, and
The unit of (c) is the electrodialysis module 42 and the ion exchange fiber module 37, and the unit of FIG. 2 (d) is the ion exchange with the two reverse osmosis membrane modules 27 connected in series. It is composed of a fiber module 37.

Next, the structure of an automatic chemical analyzer using the pure water purification module according to one embodiment of the present invention and incorporating a unitized pure water producing section will be described. Figure 3
1A and 1B are a front view and a side view of an automatic chemical analyzer according to an embodiment of the present invention. In the figure, the same reference numerals as those in FIG. Only new codes will be described.

In FIG. 3, A is an analysis unit in which a sample table, a reagent table, a reaction table and the like are incorporated,
Reference numeral 34 is a roller for sliding the pure water producing unit 18, and 35 is a roller.
This is a rail for sliding the roller 34. The pure water producing unit 18 housed in the housing is slid by the roller 34 and the rail 35, pushed into the lower portion of the analysis unit A, and incorporated into the automatic chemical analyzer.

In this way, the pure water production unit is unitized and integrated, so that the space saving of the automatic chemical analyzer can be achieved, and the pure water production unit 18 which is significantly contaminated from the analysis unit to the analysis unit. It is possible to form a piping flow path system in which piping to other portions of U is shortest. In addition, a pure water purification controller 33, a controller 38, and a data processing unit D form a hierarchical system, and feedback control of the entire apparatus is performed to reduce the running cost and achieve a predetermined water quality. Pure water can be reliably obtained.

The raw water supplied to the automatic chemical analyzer has regional characteristics, and the water temperature, PH value, hardness, for example, m.
In addition to g / l, the content rates of various metal ions such as Fe and Ca are also different. In addition, in relatively large-scale hospitals and clinical test centers, since they are used once after being stored in a water storage tank, precipitates and evaporation The influence of residues and the like will increase. In small hospitals, there are times when unavoidable use of groundwater. In addition, the required quality of pure water may vary depending on the scale of a hospital or clinical laboratory.

In such a case, if the quality of raw water, the flow rate and its change, the quality and quantity of pure water to be used, etc. are input to any of the devices constituting the hierarchical system, the hierarchical system of FIG. As shown in Fig. 2 (d), four types of unitized pure water production parts are used for running cost,
Economical points are judged, and a selection command is output from any of the devices included in the hierarchical system. According to the selection command, any of the four types of units is manually incorporated into the automatic chemical analysis device.

The application of the four types of unitized pure water production sections will be described below. For facilities that use city tap water and industrial recovered water in parallel, the unit configuration in Figure 2 (a) is selected because the industrial water contains a large amount of suspended matter. The unit shown in FIG. 2A is composed of a reverse osmosis membrane module 27 and an ion exchange resin module 36, and the tap water pressure applied to the reverse osmosis membrane module 27 and the ion exchange resin module 36. The required pure water can be obtained by controlling the pure water producing unit 18 based on the specific resistance value of the pure water obtained by passing through

In the ion exchange resin module 36 and the ion exchange fiber module 37, all of the raw water can be used as pure water, and since there is no waste water, a water supply system can be constructed efficiently. Therefore, when it is desired to increase the recovery rate of raw water during a dry season, the unit configuration shown in Fig. 2 (b) should be selected. On the other hand, the service life is short, and for example, the amount of permeated water needs to be replaced with about 200 liters of raw water, and the frequency is high, and maintenance and running costs may not always be preferable.

On the other hand, the reverse osmosis membrane module 27 and the electrodialysis module 42 have a long life because they have a self-cleaning function. For example, the amount of permeated water is 120,000 in raw water.
There is about 1, but on the other hand, 50% or more is discarded as waste water
The amount of raw water consumed is also increased because it is discarded.

In the Ca and Na analysis, in particular, the water quality of pure water has a great influence on the analysis value. Therefore, as shown in FIG. 2D, two reverse osmosis membrane modules 2 connected in series are used.
Pure water is purified by a unit having a configuration using 7. The unit having the configuration shown in FIG. 2D has an advantage that the unit having the configuration shown in FIG. 2A is further developed, the running cost becomes low, and bacteria are reduced. Further, FIG. 2 (c)
An electrodialysis module 42 and an ion exchange fiber module 37 can also be employed as shown in FIG.

In the present embodiment, the four types of unitized pure water production sections are separate units, but various pure water purification modules are connected by piping and a switching valve, and The switching valve may be switched in response to a selection command from the controller 33 to form any combination of various pure water production modules. In addition, in this embodiment,
The pure water purifying controller 33, the controller 38, and the data processing unit D are separately configured to form a hierarchical system, but these functions are integrated and one controller or two controllers are integrated. It doesn't matter.

[0053]

As described in detail above, according to the present invention, in the automatic chemical analysis device in the wet analysis method, the pure water production section is unitized by the pure water purification module and incorporated into the analysis section. Since it is integrated, it is possible to provide a downsized automatic chemical analyzer. Also, when the pure water production unit is unitized by the pure water purification module configuration, the amount of raw water used in the automatic chemical analyzer,
By designing the system so that its functions, including water quality, amount of pure water, and water quality, are optimized, and controlling the entire automatic chemical analyzer as an integrated system by the controller, data processing unit, etc. It is possible to provide an automatic chemical analyzer which improves its performance and function, is economical as a whole system, is easy to use, and has high reliability of analytical data.

[Brief description of drawings]

FIG. 1 is a schematic explanatory view including a partial block diagram of an automatic chemical analysis device according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a unit including a pure water purification module in the automatic chemical analyzer according to the embodiment of FIG.

FIG. 3 is a front view and a side view of the automatic chemical analyzer according to the embodiment of FIG.

[Explanation of symbols]

U analysis unit D data processing section A analysis section 1 reaction table 2 reaction line 3 reaction vessel 4 light source section 5 photometer 6 pipetter section 7 washing tank 8 nozzle 9 first reagent table 10 second reagent table Bull 11 ₁ , 11 ₂ , 11 ₃ Sampling section 12 Sample table 13 Float switch 14 Water tank 15 Water pump 16 Sample container 18 Pure water production section 19 Fibrous filter 20 Water source 21 Channel opening / closing valve 22 Pressure switch 23 High-pressure pump 24 Pressure monitor 25 Open / close valve 26 Squeeze valve 27 Reverse osmosis membrane module 28 Water quality meter 29 Pressure monitor 30 Pressure switch 31 Waste water inlet 32 Water quality meter 33 Pure water purification controller 34 Roller 35 Rail 36 Ion Exchange resin module 37 Ion exchange fiber module 38 Controller 40 Connection cable 42 Electrodialysis Ju - Le

Front page continuation (72) Inventor Katsuaki Araki 1040 Ichimo, Ichima, Katsuta, Ibaraki Prefecture, Hitachi Science Systems Co., Ltd. ) Innovator Naoya Ono 1040 Ichige, Ichige, Katsuta-shi, Ibaraki Hitachi Science Systems Co., Ltd. (72) Inventor Hiro Umezu 1040, Ichige, Katsuta-shi, Ibaraki Hitachi Science Systems, Inc.

Claims (4)

[Claims] 1. A reaction table having a sample table holding a sample container and a reaction line holding a reaction container row.
And the reagent table in which the reagent is held, the sample in the sample container on the sample table and the reagent in the reagent container of the reagent table are inhaled and transferred to the reaction container. A sampling unit, a pure water production unit that supplies pure water to each unit, a photometric unit that optically measures a sample that has been subjected to a reaction treatment in the reaction container, a controller that controls the operation of each unit, and In an automatic chemical analyzer comprising a data processing unit for arithmetically processing measurement data from a photometry unit, the pure water production unit is unitized by a plurality of pure water purification modules, The controller is housed in a chemical analyzer, and the controller monitors and controls the quality of pure water.
A combination of the plurality of kinds of pure water purification modules of the pure water production unit is determined according to the raw water condition and the analysis condition, and the automatic chemical analysis device is controlled together with the data processing unit as an integrated system. An automated chemical analyzer characterized by being configured. 2. The deionized water production unit is an ion exchange resin module.
4. A pure water purification unit comprising at least one of the following: a pure water purification unit, a reverse osmosis membrane module, an electrodialysis module, and an ion exchange fiber module. The automated chemical analyzer described. 3. The automatic chemical analyzer according to claim 1, wherein the controller is configured integrally with the data processing unit. 4. The controller comprises means for monitoring and controlling the quality of pure water in the pure water producing section, and a plurality of types of pure water purification modules in the pure water producing section according to raw water conditions and analysis conditions. −
3. A means for determining the combination of the data and separating the data processing unit and the means for controlling the automatic chemical analysis device as an integrated system. Automatic chemical analyzer.