JP2002311011A - Total nitrogen and/or total phosphor measuring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a total nitrogen and/or total phosphor measuring device which is simple and compact in configuration of the entire device, and capable of improving the reliability and reducing consumption of samples and reagent. SOLUTION: A light source 12 for measurement and a detector 13 for detecting the light from the light source 12 for measurement are provided on the positions across a cell 9 formed of a light transmissive material. An ultraviolet ray lamp 14 for irradiating ultraviolet rays on the cell 9 is provided, and the cell 9 is used for both decomposition and measurement.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an apparatus for measuring total nitrogen and / or total phosphorus.

[0002]

2. Description of the Related Art As a conventional total nitrogen measuring apparatus, an alkaline reagent is added to a sample to make it alkaline, and the alkaline sample is oxidized and decomposed by ultraviolet irradiation, and then an acidic reagent is added to the sample to make it acidic. Some absorbance measurement is performed in the state.

[0003] Further, as a conventional total phosphorus measuring apparatus, there is an apparatus in which an oxidizing agent is added to a sample, and the sample is oxidatively decomposed by ultraviolet irradiation, and then a reducing agent and a color former are added to perform absorption measurement.

[0004]

However, in each of the conventional total nitrogen measuring apparatus and total phosphorus measuring apparatus having the above-mentioned structure, a cell constituting a decomposition section for oxidatively decomposing a sample by ultraviolet irradiation is provided. Since the cell constituting the measurement unit for measuring the absorbance of the sample was provided separately, the overall configuration of the device became complicated and large, and the number of components such as solenoid valves increased, so the device Was also reduced in reliability. Further, since it is necessary to send the sample from the decomposition section to the measurement section, the consumption of the sample and the reagent is increased, and the running cost is increased.

SUMMARY OF THE INVENTION The present invention has been made in consideration of the above-mentioned matters, and has as its object the structure of the entire apparatus is simple and compact, and the reliability can be improved.
It is a further object of the present invention to provide a total nitrogen and / or total phosphorus measurement device that can reduce the consumption of samples and reagents.

[0006]

Means for Solving the Problems To achieve the above object, a total nitrogen and / or total phosphorus measuring apparatus of the present invention comprises:
A light source for measurement and a detector for detecting light from the light source for measurement are provided at positions sandwiching a cell made of a light-transmitting material, and an ultraviolet lamp for irradiating the cell with ultraviolet light is provided. The cell is used for both decomposition and measurement (claim 1).

[0007] With the above configuration, the overall configuration of the apparatus is simple and compact, the reliability can be increased, and further, the total nitrogen and / or total phosphorus that can reduce the consumption of samples and reagents can be reduced. It is possible to provide a measuring device.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an explanatory view schematically showing a configuration of a total nitrogen measuring device D according to a first embodiment of the present invention. The total nitrogen measuring device D is for measuring the concentration of total nitrogen in the sample S,
A tank 2 for storing blank water, a dilution tank 4 to which the sample S from the supply unit 1 and the blank water from the tank 2 are respectively supplied via a first measuring unit 3;
The sample S in the diluting tank 4 is supplied via the second measuring section 5, and the reagent 9 from the three reagent supply paths 6, 7, 8 is supplied to the cell 9, and the sample 9 is supplied to the cell 9. Discharge channel 1 for discharging (drain or waste liquid) the fluid (sample S, blank water, reagent, etc.) and the fluid (sample S, blank water, etc.) supplied into the dilution tank 4.
0.

The first measuring section 3 measures the sample S introduced from the supply section 1 to a predetermined amount, sends the sample S to the dilution tank 4, and sends the blank water introduced from the tank 2 to the dilution tank 4. , And is sent to the dilution tank 4 after being measured to a predetermined amount.

The diluting tank 4 is for diluting the sample S by a predetermined amount with blank water. The sample S and the blank water in the first measuring section 3 are supplied in predetermined amounts. Then, a sample S diluted to a predetermined time is placed on the downstream side of the dilution tank 3 in the second measuring section 5.
In addition to the diluted sample supply path 4a for sending the sample S and the blank water in the dilution tank 4,
The outlet flow path 4b for leading to the outlet is connected. In addition,
When the concentration of the sample S is sufficiently low, the dilution of the sample S in the dilution tank 4 is not performed, and the sample S from the supply unit 1 is sent to the cell 9 via the second measuring unit 5 as it is. .

The second measuring section 5 is for measuring the diluted sample S introduced from the diluting tank 4 to a predetermined amount and sending it to the cell 9.

The reagent supply path 6 is for supplying an aqueous solution of potassium peroxodisulfate as an oxidizing reagent to the cell 9, and a reagent tank 6 a containing an aqueous solution of potassium peroxodisulfate is connected upstream thereof. Have been.

The reagent supply path 7 is for supplying an aqueous solution of sodium hydroxide as an alkaline reagent to the cell 9, and a reagent tank 7a containing an aqueous solution of sodium hydroxide is connected to an upstream side thereof. I have.

The reagent supply path 8 is for supplying a hydrochloric acid solution as an acidic reagent to the cell 9, and a reagent tank 8a containing a hydrochloric acid solution (or a sulfuric acid solution) is provided upstream thereof. It is connected.

A reagent measuring section 11 is provided in the middle of each of the reagent supply paths 6, 7, 8 by which the reagent from each of the reagent tanks 6a, 7a, 8a is measured. After a predetermined amount is obtained, the data is sent to the cell 9.

FIG. 2 is an explanatory view schematically showing the structure of the cell 9, and FIGS. 3A and 3B are a perspective view and a plan view schematically showing the structure of the cell 9. A measurement light source 12 and a detector 13 for detecting light from the measurement light source 12 are provided at positions sandwiching a cell 9 made of a light-transmitting material, and an ultraviolet ray for irradiating the cell 9 with ultraviolet light. A heating means 15 for heating the lamp 14 and the inside of the cell 9 is provided, and the cell 9 is used for both decomposition for decomposing the sample S and measurement for measuring the sample S. is there.

The cell 9 is made of, for example, quartz or Pyrex (registered trademark), and an irradiated portion 9a for irradiating the sample S in the cell 9 with light from the measurement light source 12 and light from the ultraviolet lamp 14. And the irradiated portion 9a
A connecting portion 9b connected to a pipe from the second measuring portion 5 and the reagent supply passages 6, 7, 8; and a small-diameter portion connected to a lower portion of the irradiated portion 9a. 9c.

In the irradiated portion 9a of the cell 9, the surface facing the measurement light source 12 and the surface facing the detector 13 are formed so as to be substantially flat and parallel to each other. The optical path from 12 to the detector 13 is not obstructed by the side wall of the cell 9.
In this embodiment, the cross section of the irradiated portion 9a has a substantially rectangular tube shape.

The connecting section 9b of the cell 9 is configured such that its cross section is larger than the cross section of the irradiated section 9a. The shape is such that the supply paths 6, 7, 8 are easily connected (for example, a cylindrical shape).

An opening / closing valve (not shown) is provided below the small diameter portion 9c of the cell 9, and the opening / closing valve is opened to allow the liquid in the irradiated portion 9a to flow in the irradiated portion 9a. It is configured so that it can be derived from Then, once the liquid derived from the inside of the irradiated portion 9a is pushed up and the on-off valve is closed, the liquid can be returned to the inside of the irradiated portion 9a. By repeating the operation of moving the liquid in and out, the liquid can be agitated.

The measuring light source 12 is, for example, a pulse-lit xenon lamp, and an interference filter (not shown) is arranged between the measuring light source 12 and the cell 9. From the cell 9 becomes ultraviolet light having a predetermined wavelength (for example, ultraviolet light having a wavelength of 220 nm).
It is irradiated to.

The detector 13 is, for example, an ultraviolet detector comprising a semiconductor detector.

The ultraviolet lamp 14 is, for example, a cold-cathode low-pressure mercury lamp for irradiating ultraviolet light having a predetermined wavelength (for example, ultraviolet light having a wavelength of 185 nm and / or ultraviolet light having a wavelength of 254 nm). The sample S supplied into the cell 9 is irradiated with ultraviolet rays from a cold-cathode low-pressure mercury lamp to convert all nitrogen compounds contained in the sample S into nitrate ions. The UV lamp 14 is not limited to a cold cathode low-pressure mercury lamp, but may be another lamp such as a hot cathode low-pressure mercury lamp.

The ultraviolet lamp 14 is provided singly or plurally at a position where light from the measurement light source 12 to the detector 13 via the cell 9 is not obstructed. For example, the two ultraviolet lamps 14 and 14 are provided at positions sandwiching the cell 9 so that a line connecting the two ultraviolet lamps 14 and 14 and a line connecting the measurement light source 12 and the detector 13 are substantially orthogonal to each other. May be configured.

The heating means 15 is composed of, for example, two seal heaters, and the total capacity of the two seal heaters is 11.5 W. And heating means 15
Is provided at a position which is suitable for keeping the cell 9 at a suitable temperature (for example, 60 ° C.), and which does not hinder light from the measurement light source 12 to the detector 13 via the cell 9. . For example, a substantially rectangular parallelepiped block 16 surrounding the irradiated portion 9a of the cell 9 may be provided, and the heating means 15 may be provided inside or outside the block 16. In this case, for example, an ultraviolet-transparent cell window (not shown) or the like may be provided so that the block 16 does not obstruct the light from the measurement light source 12 via the cell 9 to the detector 13. The ultraviolet lamp 14 may be provided in the block 16.

Next, the operation of the total nitrogen measuring device D having the above configuration will be described. First, the sample S from the supply unit 1 is measured in the first measuring unit 3, and a predetermined amount of the sample S is sent to the dilution tank 4.

If it is necessary to dilute the sample S, a predetermined amount of blank water is sent to the dilution tank 4 after the blank water from the tank 2 is measured in the first measuring section 3. . When the concentration of the sample S is sufficiently low, the supply of the blank water to the dilution tank 4 is not performed.

The sample S diluted in the dilution tank 4 as described above and having an appropriate concentration is measured in the second measuring section 5, and a predetermined amount of the sample S is sent to the cell 9.

Then, an aqueous solution of potassium peroxodisulfate as an oxidizing reagent and an aqueous solution of sodium hydroxide as an alkaline reagent are supplied into the cell 9 from the reagent supply paths 6 and 7, and mixed with the sample S in the cell 9. Will be. At this time, if ions of heavy metals such as Fe are contained in the sample S, the ions react with the aqueous sodium hydroxide solution to generate heavy metal hydroxides.

Thereafter, the ultraviolet rays are irradiated from the ultraviolet lamps 14 into the cell 9 maintained at 60 ° C. by the heating means 15 for about 15 minutes, for example. By this ultraviolet irradiation, the nitrogen compound contained in the sample S is oxidized to nitrate ions.

The sample S, which has been oxidatively decomposed by the ultraviolet irradiation, is once removed from the irradiated portion 9a of the cell 9 to the small diameter portion 9c.
, And at this time, the heavy metal hydroxide may be removed by passing the sample S through a filter (not shown).

The sample S filtered as described above is sent to the second measuring section 5 to be weighed to a predetermined amount, and then supplied again into the cell 9 and to the reagent supply path. From Step 8, a hydrochloric acid solution (or a sulfuric acid solution may be used) as an acidic reagent is added, and the sample S
Is adjusted to be about 2 to 3. In this case, even if the sample S becomes acidic, heavy metal ions can be removed from the sample S by removing the heavy metal hydroxide as described above.
It does not occur inside.

The pH of the sample S whose acidity has been adjusted is measured in the cell 9 for ultraviolet absorbance at a wavelength of 220 nm. Then, in an arithmetic processing unit (not shown),
A predetermined process is performed based on the absorbance, and the sample S
Can be obtained. In this case, a more accurate result can be obtained by performing dark correction, zero point correction, and the like together.

Then, after the measurement is performed as described above,
The sample S is sent out from the discharge channel 10.

In the total nitrogen measuring apparatus D having the above configuration, the cell 9 is used for both the decomposition for decomposing the sample S and the measurement for measuring the sample S. Compared to a conventional total nitrogen measurement device that performs measurement and measurement at separate points, the overall configuration of the device is simpler and more compact, and the number of components such as solenoid valves is reduced, which increases reliability. Can be raised, and the liquid transport distance of the sample S and the reagent can be shortened, so that the loss accompanying the liquid transport can be reduced, the consumption of the sample S and the reagent can be reduced, and the running cost can be reduced. It becomes possible to plan.

In the total nitrogen measuring apparatus D having the above configuration, the reagent supply paths 6 and 7 are connected to the cell 9. However, the present invention is not limited to such a configuration. May be connected to the dilution tank 4.

Further, in the total nitrogen measuring apparatus D having the above configuration, when heavy metal ions are contained in the sample S, they may be removed by a filter, but the present invention is not limited to such a configuration. For example, even when the purity of the aqueous solution of potassium peroxodisulfate as the oxidizing reagent or the aqueous solution of sodium hydroxide as the alkaline reagent is low and heavy metal ions such as copper are mixed therein, the heavy metal ions are removed. can do.

FIG. 1 is also an explanatory view schematically showing a configuration of a total phosphorus measuring apparatus D ₂ according to a second embodiment of the present invention. Note that members having the same structure as those shown in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted. The total phosphorus measuring device D ₂ is different from the total nitrogen measuring device D of the first embodiment in that the reagent supply paths 7 and 8 each have a reagent supply path 1.
7 and 18 are different.

That is, the total phosphorus measuring device D ₂ is for measuring the concentration of total phosphorus in the sample S, and includes a supply section 1 for the sample S and a tank 2 for storing blank water.
And the sample S from the supply unit 1 and the tank 2
And the sample S in the dilution tank 4 is supplied through the second measurement section 5 and the three reagent supply paths 6 are provided. , 17, 18 and the fluid (sample S, blank water, reagent, etc.) supplied to the cell 9 and the fluid supplied to the dilution tank 4 (sample S, blank) And a discharge flow path 10 for discharging (water or waste liquid).

In the apparatus for measuring total phosphorus D ₂ , a reagent supply path 17 for supplying an aqueous solution of L-ascorbic acid as a reducing reagent to the cell 9 is employed instead of the reagent supply path 7 in the first embodiment. The reagent tank 17a connected to the upstream side of the reagent supply path 17 contains an aqueous L-ascorbic acid solution as a reducing reagent.

In the total phosphorus measuring apparatus D ₂ , a sulfuric acid solution of ammonium molybdate / antimony potassium tartrate as a coloring reagent is supplied to the cell 9 instead of the reagent supply path 8 in the first embodiment. A reagent tank 18a connected to the upstream side of the reagent supply path 18 stores a sulfuric acid solution of ammonium molybdate / potassium antimonyl tartrate as a coloring reagent. You.

A reagent measuring section 11 is provided in the middle of each of the reagent supply paths 17, 18, and the reagent from each of the reagent tanks 17a, 18a is measured by the reagent measuring section 11 to a predetermined amount. Is sent to the cell 9.

Other configurations of the total phosphorus measuring device D ₂ are the same as those of the total nitrogen measuring device D of the first embodiment, and therefore, description thereof will be omitted.

Next, the operation will be described of total phosphorus measuring device D _2. First, the sample S from the supply unit 1
Is measured in the first measuring section 3, and a predetermined amount of the sample S is sent to the dilution tank 4.

If the sample S needs to be diluted, the blank water from the tank 2 is measured in the first measuring section 3 and then a predetermined amount of blank water is sent to the dilution tank 4. . When the concentration of the sample S is sufficiently low, the supply of the blank water to the dilution tank 4 is not performed.

The sample S diluted in the dilution tank 4 as described above and having an appropriate concentration is measured in the second measuring section 5, and a predetermined amount of the sample S is sent to the cell 9.

Then, an aqueous solution of potassium peroxodisulfate as an oxidizing reagent is supplied from the reagent supply path 6 into the cell 9 and mixed with the sample S in the cell 9.

Thereafter, the ultraviolet rays are irradiated from the ultraviolet lamps 14 into the cell 9 kept at 95 ° C. by the heating means 15 for about 30 to 45 minutes, for example. By this ultraviolet irradiation, the phosphorus compound contained in the sample S is converted into orthophosphate ions.

Subsequently, the sample S is sent to the second measuring section 5 to be weighed to a predetermined amount, and then supplied again to the cell 9. An aqueous solution of L-ascorbic acid as a reducing reagent and a sulfuric acid solution of ammonium molybdate / potassium antimonyl tartrate as a coloring reagent are supplied from the reagent supply paths 17 and 18.

Then, by controlling the heating means 15, the temperature in the cell 9 is adjusted to 40 to 60 ° C., molybdenum blue is generated in the cell 9, and the absorbance at a wavelength of 880 nm is measured. Next, in an arithmetic processing unit (not shown), a predetermined process is performed based on the absorbance, and the concentration of total phosphorus contained in the sample S can be obtained. In this case, a more accurate result can be obtained by performing dark correction, zero point correction, and the like together.

Then, after the measurement is performed as described above,
The sample S is sent out from the discharge channel 10.

[0052] Note that the effect obtained by the total phosphorus measuring device D ₂ having the above structure, since it is the same as the total nitrogen measurement device D in the first embodiment, description thereof is omitted.

[0053] In total phosphorus measuring device D ₂ the above structure, but the reagent supply passage 6 is connected to the cell 9 is not limited to such a configuration, for example, the dilution reagent supply channel 6 It may be connected to the tank 4.

In the above two embodiments, the wavelength of light emitted from the measuring light source 12 or the ultraviolet lamp 14 to the cell 9 is changed by using, for example, an interference filter or the like, so that turbidity correction and COD correction can be performed. The measurement may be performed. For example, in order to perform the turbidity correction by changing the wavelength of the measurement light source 12, the original measurement wavelength 22
In addition to the measurement at 0 nm, a so-called two-wavelength measurement that performs measurement at an appropriate wavelength in the range of 400 to 600 nm (for example, 546 nm) may be performed.

When the sample S is oxidized and decomposed by the irradiation of the ultraviolet light from the ultraviolet lamp 14, the ultraviolet light from the ultraviolet lamp 14 reflected and refracted in the cell 9 is monitored by the detector 13. Deterioration of the ultraviolet lamp 14 can be determined.

Further, since the end of the oxidative decomposition of the sample S by the irradiation of the ultraviolet ray from the ultraviolet lamp 14 can be judged by the monitor, the loss of time from the end of the oxidative decomposition to the start of the preparation for measurement can be reduced. Sample S which is being oxidized and decomposed
Because the absorbance of ultraviolet light can be measured, from the absorbance,
It is possible to derive the concentration of the sample S.

[0057] FIG. 4 is an explanatory view schematically showing construction of a total nitrogen-Total phosphorus measuring apparatus D ₃ a according to a third embodiment of the present invention. Note that members having the same structure as those shown in the above two embodiments are denoted by the same reference numerals, and description thereof will be omitted. The total nitrogen / total phosphorus measuring device D ₃ is for measuring the concentration of total nitrogen and total phosphorus in the sample S,
A supply unit 1 for the sample S, a tank 2 for storing blank water, a dilution tank 4 to which the sample S from the supply unit 1 and the blank water from the tank 2 are respectively supplied via a first measuring unit 3; The sample S in the dilution tank 4 is supplied through the second measuring section 5 and the two cells 9N and 9P to which the reagents from the five reagent supply paths 6, 7, 8, 17, and 18 are supplied. And the fluid (sample S, blank water, reagent, etc.) supplied to these cells 9N, 9P and the fluid (sample S, blank water, etc.) supplied to the dilution tank 4 are discharged (drainage or waste liquid). And a discharge channel 10 for performing the operation. Note that in FIG.
Is a manifold to which the reagent supply pipes 6, 7, 8, 17, 18 and the first measuring section 3, the second measuring section 5 and the like are connected;
Is a pump unit for feeding a liquid such as a sample S, blank water, a reagent, etc., and is connected to one end of the manifold 19.

The cell 9N corresponds to the cell 9 in the total nitrogen measuring apparatus D of the first embodiment. The cell 9N measures the concentration of total nitrogen in the sample S shown in the first embodiment. Oxidative decomposition and absorbance measurement are performed. Therefore, reagent supply paths 6, 7, 8 are connected to the cell 9N.

[0059] The cell 9P is equivalent to the cell 9 in total phosphorus measuring device D ₂ of the second embodiment, in the cell 9P, the concentration of total phosphorus in the sample S shown in the second embodiment The oxidative decomposition and the absorbance measurement for the measurement are performed. Therefore, reagent supply paths 6, 17, and 18 are connected to the cell 9P.

The cells 9N and 9P are connected in parallel to the dilution tank 4.

Next, the operation of the total nitrogen-Total phosphorus measuring apparatus D ₃ having the above structure. First, the sample S from the supply unit 1 is measured in the first measuring unit 3, and a predetermined amount of the sample S is sent to the dilution tank 4.

If the sample S needs to be diluted, the blank water from the tank 2 is measured in the first measuring section 3 and then a predetermined amount of blank water is sent to the dilution tank 4. . When the concentration of the sample S is sufficiently low, the supply of the blank water to the dilution tank 4 is not performed.

The sample S diluted to an appropriate concentration in the dilution tank 4 as described above is weighed in the second weighing section 5, and a predetermined amount of the sample S is stored in the cells 9N and 9P.
Sent to each.

The cell 9N to which a predetermined amount of the sample S has been sent is further supplied with an aqueous solution of potassium peroxodisulfate as an oxidizing reagent and an aqueous solution of sodium hydroxide as an alkaline reagent from the reagent supply paths 6 and 7. 9N
And mixed with the sample S in the cell 9N. At this time, if ions of heavy metals such as Fe are contained in the sample S, the ions react with the aqueous sodium hydroxide solution to generate heavy metal hydroxides.

Thereafter, ultraviolet rays are irradiated from the ultraviolet lamps 14, 14 into the cell 9N kept at 60 ° C. by the heating means 15, for about 15 minutes, for example. By this ultraviolet irradiation, the nitrogen compound contained in the sample S is oxidized to nitrate ions.

The sample S that has been oxidatively decomposed by the ultraviolet irradiation is once removed from the irradiated portion 9a of the cell 9N by the small-diameter portion 9a.
c, the heavy metal hydroxide may be removed by passing the sample S through a filter (not shown).

The sample S filtered as described above is sent to the second measuring section 5 to be weighed to a predetermined amount, and then supplied again to the cell 9N, and to the reagent supply path. From step 8, a hydrochloric acid solution (or a sulfuric acid solution may be added) as an acidic reagent is added, and the pH of the sample S is adjusted to be about 2 to 3. in this case,
Even if the sample S becomes acidic, heavy metal ions will not be generated in the sample S if the heavy metal hydroxide is removed as described above.

For the sample S whose pH has been adjusted to be acidic, the UV absorbance at a wavelength of 220 nm is measured in the cell 9. Then, in an arithmetic processing unit (not shown),
A predetermined process is performed based on the absorbance, and the sample S
Can be obtained. In this case, a more accurate result can be obtained by performing dark correction, zero point correction, and the like together.

Then, after the measurement is performed as described above,
The sample S is sent out from the discharge channel 10.

On the other hand, an aqueous solution of potassium peroxodisulfate as an oxidizing reagent is further supplied from the reagent supply path 6 to the cell 9P to which the predetermined amount of the sample S has been sent. Will be mixed with S.

Thereafter, the ultraviolet rays are radiated from the ultraviolet lamps 14 into the cell 9P maintained at 95 ° C. by the heating means 15, for about 30 to 45 minutes, for example. By this ultraviolet irradiation, the phosphorus compound contained in the sample S is converted into orthophosphate ions.

Subsequently, the sample S is sent to the second measuring section 5 to be weighed to a predetermined amount, and then supplied again to the cell 9P. An aqueous solution of L-ascorbic acid as a reducing reagent and a sulfuric acid solution of ammonium molybdate / potassium antimonyl tartrate as a coloring reagent are supplied from the reagent supply paths 17 and 18.

Then, by controlling the heating means 15, the temperature in the cell 9P is adjusted to 40-60 ° C.
Molybdenum blue is generated in P, and the absorbance at a wavelength of 880 nm is measured. Next, in an arithmetic processing unit (not shown), a predetermined process is performed based on the absorbance, and the concentration of total phosphorus contained in the sample S can be obtained.
In this case, a more accurate result can be obtained by performing dark correction, zero point correction, and the like together.

Then, after the measurement is performed as described above,
The sample S is sent out from the discharge channel 10.

The effect obtained by the total nitrogen / total phosphorus measuring device D ₃ having the above configuration is the effect obtained by the total nitrogen measuring device D of the first embodiment and the total phosphorus measuring device D _{2 of} the second embodiment. Is the same as

It is needless to say that the structure shown in the first and second embodiments may be applied to the third embodiment.

In the above three embodiments, the cells 9, 9
Although both the ultraviolet lamp 14 and the heating means 15 are provided for N and 9P, only one of them may be provided.

[0078]

As described above, according to the present invention having the above-described structure, the structure of the entire apparatus is simple and compact, and the reliability can be improved.
Further, it is possible to provide a total nitrogen and / or total phosphorus measurement device capable of reducing the consumption of samples and reagents.

[Brief description of the drawings]

FIG. 1 is an explanatory view schematically showing a configuration of a total nitrogen measuring device according to a first embodiment of the present invention and a total phosphorus measuring device according to a second embodiment.

FIG. 2 is an explanatory diagram schematically showing a configuration of a cell in all embodiments of the present invention.

FIGS. 3A and 3B are a perspective view and a plan view schematically showing the configuration of the cell.

FIG. 4 is an explanatory view schematically showing a configuration of a total nitrogen and total phosphorus measuring device according to a third embodiment of the present invention.

[Explanation of symbols]

9 cell, 12 light source for measurement, 13 detector, 14 ultraviolet lamp, 15 heating means, D total nitrogen measuring device.

Continued on the front page (51) Int.Cl. ⁷ Identification code FI Theme coat II (Reference) G01N 21/78 G01N 21/78 C (72) Inventor Jiro Sakai 18 Kichijoin-mae Kawaramachi, Minami-ku, Kyoto-shi, Kyoto Kos Co., Ltd. (72) Inventor Noboru Ishifuji 18 Kichijoin-mae Kawaramachi, Minami-ku, Kyoto-shi, Kyoto F-term (reference) 2G042 AA01 AA05 BB16 BD12 CA02 CB03 DA01 DA03 DA05 DA08 DA09 EA07 FA01 FA02 FA04 FA05 FA11 GA01 HA02 HA03 HA05 HA06 HA07 2G054 AA02 AA10 AB08 AB10 BB13 CA30 CB03 CE01 EA04 EA09 EB01 FA06 FA19 GA02 GA03 GB01 GB05 JA08 JA09 JA20 2G057 AA01 AB02 AB03 AB06 AC01 AD02 BA01 BB01 BB04 EA06 2G059 A0401 BB04 DD06 DD06 DD06 HH03 HH06 JJ03 KK01

Claims (1)

[Claims] 1. A light source for measurement and a detector for detecting light from the light source for measurement are provided at a position sandwiching a cell made of a light-transmitting material, and ultraviolet light for irradiating the cell with ultraviolet light. An apparatus for measuring total nitrogen and / or total phosphorus, wherein a lamp is provided, and the cell is used for both decomposition and measurement.