JP7171373B2 - Reaction vessel for soil analysis - Google Patents

Description

The present invention relates to a reaction container for soil analysis used for analyzing soil components, which are components of soil.

Conventionally, Patent Literature 1 discloses a reaction container for soil analysis.
A soil analysis reaction container disclosed in Patent Document 1 is a container for reacting a soil component in a soil solution containing a soil component with a reaction reagent, and includes a plurality of liquid storage chambers in which the reaction reagent is enclosed. have Reaction reagents corresponding to different soil components are stored in the plurality of liquid storage chambers. When a soil solution is injected into each liquid storage chamber, the soil component and the reaction reagent are mixed and colored. By irradiating LED light there and sensing the transmittance of the light, it is possible to measure the amounts of a plurality of types of soil components in the soil to be analyzed.

JP 2017-198623 A

The reaction container disclosed in Patent Document 1 is a reaction container for analyzing a plurality of types of soil components in one analysis target soil, so when performing component analysis of a plurality of analysis target soils, the analysis efficiency is improved. I have a bad problem.
SUMMARY OF THE INVENTION An object of the present invention is to provide a reaction container for soil analysis that can improve analysis efficiency when performing component analysis of a plurality of soils to be analyzed.

A reaction container for soil analysis according to an aspect of the present invention is an injection part for injecting a soil solution containing soil components, and reacts the soil components in the soil solution injected from the injection part with a reaction reagent. A plurality of sections having a plurality of reaction chambers for and a soil solution supply path for supplying the soil solution injected from the injection part to each reaction chamber ,
The plurality of sections are vertically stacked .
Further, the plurality of reaction chambers in each section are chambers for reacting different soil components.

Each section also has an indicator for associating with the injected soil solution.
Further, each section is formed in a disc shape .

According to the above configuration, by injecting a different soil solution to be analyzed into each section, component analysis of a plurality of soils to be analyzed can be performed. As a result, analysis efficiency can be improved.

1A and 1B are a plan view and a partial plan cross-sectional view of a reaction vessel according to a first embodiment; FIG. 2 is a cross-sectional view taken along line G1-G1 in FIG. 1; FIG. FIG. 2 is a cross-sectional view taken along line G2-G2 of FIG. 1; FIG. 4 is a configuration diagram showing a method of sampling soil to be injected into a reaction vessel; It is a schematic diagram showing an outline of an analyzer. It is a sectional view showing a modification of a 1st embodiment. FIG. 4 is a plan view of a reaction vessel according to a second embodiment; FIG. 11 is a plan view of a reaction vessel according to a third embodiment; FIG. 11 is a front view of a reaction container according to a third embodiment;

Hereinafter, embodiments of the present invention will be described with appropriate reference to the drawings.
FIG. 1 shows a soil analysis reaction container 1 (hereinafter simply referred to as a reaction container) according to the first embodiment. The reaction container 1 is a container used in an analyzer that analyzes (measures) the amount of soil components that are components of soil (components contained in soil), and is a soil component in a soil solution containing soil components. , and reaction reagents to cause a color reaction.

As shown in FIG. 1, the reaction vessel 1 has a square block-shaped vessel body 2 and a plurality of sections 3 .
As shown in FIGS. 1 to 3, the container body 2 is made of a transparent material and has translucency (property of high light transmission). The container body 2 includes a rectangular upper wall surface 2a, a rectangular lower wall surface 2b having the same shape as the upper wall surface 2a, and four side wall surfaces connecting corresponding edges of the upper wall surface 2a and the lower wall surface 2b in the vertical direction. (first side wall surface 2c to fourth side wall surface 2f).

In the first embodiment, the direction along the first side wall surface 2c (one side surface) of the container body 2 is referred to as the first direction (arrow A1 direction in FIG. 1), and the direction along the second side wall surface 2d (first direction A1 and a direction crossing (perpendicular to) the vertical direction) is referred to as a second direction (arrow A2 direction in FIG. 1).
As shown in FIG. 1, the multiple sections 3 are arranged side by side in the first direction A1. In this embodiment, the plurality of sections 3 includes five sections 3 (first section 3A to fifth section 3E). Note that the number of sections 3 may be two, three, four, or six or more.

Each section 3 includes an injection part 4 for injecting the soil solution, a plurality of reaction chambers 5 for reacting the soil components in the soil solution injected from the injection part 4 with the reaction reagent 7, and the injection part 4. and a soil solution supply path 6 for supplying the soil solution injected from the reaction chamber 5 to each reaction chamber 5 . That is, the reaction vessel 1 has a plurality of sections 3 each having an injection section 4 , a plurality of reaction chambers 5 and soil solution supply channels 6 . Each section 3 is filled with a soil solution of a different soil to be analyzed. Therefore, the reaction container 1 can correspond to component analysis of a plurality of soils to be analyzed. In this embodiment, one reaction vessel 1 is used for component analysis of five soils to be analyzed. The first section 3A to fifth section 3E are of similar construction.

As shown in FIG. 1, the injection part 4 is provided on one end side in the second direction A2. A soil solution can be injected into the injection part 4 from above. A plurality of reaction chambers 5 are arranged side by side along the second direction A2. In this embodiment, six reaction chambers 5 (first reaction chamber 5A to sixth reaction chamber 5F) are formed side by side along the second direction A2. Each reaction chamber 5 is formed independently of each other and does not communicate with each other. Each reaction chamber 5 contains a reaction reagent 7 that mixes with soil components to cause a color reaction. That is, the reaction chamber 5 contains a reaction reagent 7 corresponding to the soil component to be analyzed. Examples of the reaction reagent 7 include nitrogen (nitrate nitrogen and ammonia nitrogen), which are important elements for the growth of crops (called the three elements of fertilizer), phosphoric acid, potassium, and calcium and magnesium, which are minerals. It is a corresponding (reacting) reagent. In addition, the reaction reagent mentioned here is an example and is not limited. The reactive reagent may be, for example, a reactive reagent for analyzing pH, lime, or the like. Moreover, the reaction reagent may be solid or liquid.

Reaction reagents 7 accommodated in each reaction chamber 5 in each section 3 contain reaction reagents 7 corresponding to different soil components for each reaction chamber 5 . That is, the plurality of reaction chambers 5 in each section 3 are chambers for reacting different soil components. To explain this with a specific example, as shown in the left diagram of FIG. 1, a reaction reagent 7A corresponding to nitrate nitrogen is contained in the first reaction chamber 5A, and contains a reaction reagent 7B corresponding to ammonia nitrogen, a third reaction chamber 5C contains a reaction reagent 7C corresponding to phosphoric acid, and a fourth reaction chamber 5D contains a reaction reagent 7D corresponding to potassium. , the fifth reaction chamber 5E contains a reaction reagent 7E corresponding to calcium, and the sixth reaction chamber 5F contains a reaction reagent 7F corresponding to magnesium. This makes it possible to measure (analyze) the amounts of a plurality of types of soil components in the soil to be analyzed. Note that the correspondence relationship of the reaction reagent 7 with respect to the reaction chamber 5 is not limited to the example described above.

Each section 3 contains a reaction reagent 7 corresponding to the same soil component. That is, the same reaction reagent 7 is accommodated in each of the first reaction chambers 5A in the first section 3A to the fifth section 3E, and the same reaction reagent is accommodated in the second reaction chambers 5B in the first section 3A to the fifth section 3E. 7 is accommodated, the same reaction reagent 7 is accommodated in the third reaction chamber 5C in the first section 3A to the fifth section 3E, and the same reaction reagent 7 is accommodated in the fourth reaction chamber 5D in the first section 3A to the fifth section 3E. The reaction reagent 7 is accommodated, the same reaction reagent 7 is accommodated in the fifth reaction chamber 5E in the first section 3A to the fifth section 3E, and the sixth reaction chamber 5F in the first section 3A to the fifth section 3E , the same reaction reagent 7 is accommodated.

As shown in FIG. 1 , the soil solution supply channel 6 has a first supply channel 8 communicating with the injection part 4 and a plurality of second supply channels 9 branched from the first supply channel 8 . In each section 3, a first supply passage 8 is formed along the second direction from the injection section 4 to the sixth reaction chamber 5F. The first supply path 8 is formed to be spaced apart from the plurality of reaction chambers 5 in the first direction A1.
The second supply channel 9 is a channel that connects the first supply channel 8 and the reaction chamber 5, and is provided for each reaction chamber. Specifically, the second supply path 9 includes a first path 9A that communicates the first reaction chamber 5A and the first supply path 8, and a second path 9B that communicates the second reaction chamber 5B and the first supply path 8. , a third channel 9C communicating the third reaction chamber 5C and the first supply channel 8, a fourth channel D communicating the fourth reaction chamber 5D and the first supply channel 8, and a fifth reaction chamber 5E A fifth channel 9E communicating with the first supply channel 8 and a sixth channel 9F communicating the sixth reaction chamber 5F and the first supply channel 8 are included.

Therefore, when the soil solution is injected from the injection part 4 , the soil solution flows through the first supply channel 8 and also flows into the corresponding reaction chamber 5 from each of the second supply channels 9 . When the soil solution flows into the reaction chambers 5, the soil components in the soil solution and the reaction reagent 7 are mixed in each reaction chamber 5 to cause a color reaction. Since the reaction vessel 1 has a plurality of sections 3, component analysis of a plurality of soils to be analyzed can be performed at once.

As shown in Figure 1, each section 3 has an indicator 10 for associating the injected soil solution. Specifically, the indicator portion 10 includes a first indicator portion 10A provided in the first section 3A, a second indicator portion 10B provided in the second section 3B, and a third indicator portion 10B provided in the third section 3C. They are an indicator portion 10C, a fourth indicator portion 10D provided in the fourth section 3D, and a fifth indicator portion 10E provided in the fifth section 3E. The index portion 10 is configured by, for example, a sticker.

Next, the sampling of the soil to be analyzed will be described.
As shown in FIG. 4, a sampling field H1 from which soil is to be sampled is divided into a plurality of areas Qn (n=1, 2, 3, . . . n). The section of the harvested field H1 is divided into the harvested field H1 by a fixed terminal such as a personal computer (PC), a mobile terminal such as a smartphone, a tablet, a PDA, or a management computer such as a server to which the fixed terminal and the mobile terminal can be connected. On the other hand, this is done by creating a mesh-type map divided into a plurality of areas Qn each having a predetermined vertical length L1 and horizontal length L2.

Next, a sampling position Pn is determined for each of the plurality of areas Qn. If there is one sampling position Pn, it is, for example, the central position of the area Qn. It should be noted that there may be two or more collection positions Pn for each area Qn. When multiple samples of soil are collected from each area Qn, they are mixed to form one soil sample.
Soil is sampled by, for example, an operator or a sampler. When the worker or the sampling machine is positioned at the scheduled sampling position, the worker is notified that the sampling position Pn has been reached. The sampling device may be a hand sampler that samples field soil by pressing a cylinder against the ground of the field, a scoop, or other structure.

Next, when the collection is completed in all the areas Qn in the collection field H1, the soil solution 11 is generated after the collected soil is dried.
As shown in FIG. 4, soil solution 11 is produced by extraction vessel 12 .
Here, generation of the soil solution 11 of the soil sample 13, which is the soil sampled in the areas Q1 to Q5, will be described.

Each soil sample 13 is placed in a different extraction vessel 12 . Specifically, the soil sample 13A collected in the area Q1 is put into the extraction container 12A, the soil sample 13B collected in the area Q2 is put into the extraction container 12B, and the soil sample 13C collected in the area Q3 is put into the extraction container 12C. , the soil sample 13D collected in the area Q4 is put into the extraction container 12D, and the soil sample 13E collected in the area Q5 is put into the extraction container 12E.

The extraction container 12 is filled with an extraction liquid (liquid for extracting components) together with the soil sample 13 . The extract may be placed in the extraction vessel 12 beforehand, may be placed together with the soil sample 13, or may be placed after the soil sample 13 is placed.
Next, the soil solution 11 is produced by shaking the extraction container 12 . The produced soil solution 11 is filtered and put into the reaction vessel 1 after filtering. In the illustrated example, the soil solution 11A produced in the extraction vessel 12A is injected from the injection part 4 of the first section 3A, and the soil solution 11B produced in the extraction vessel 12B is injected from the injection part 4 of the second section 3B. The soil solution 11C produced in the extraction container 12C is injected from the injection part 4 of the third section 3C, the soil solution 11D produced in the extraction container 12D is injected from the injection part 4 of the fourth section 3D, The soil solution 11E produced in the extraction container 12E is injected from the injection part 4 of the fifth section 3E.

Different identification numbers are assigned to the index portions 10 of each section 3 in order from the first index portion 10A to the fifth index portion 10E. As a result, the areas Q1 to Q5 from which the soil samples 13A to 13D were collected can be associated (corresponded) with the injected soil solutions 11A to 11D.
The soil samples 13 of the remaining areas Qn are also injected into other reaction vessels 1 in the same manner as described above. A different identification number is assigned to the index portion 10 of each reaction container 1 .

FIG. 5 shows an analyzer 14 for measuring the amount (content) of soil components in the soil solution 11 injected into the reaction vessel 1 (performing soil analysis). The analyzer 14 measures the optical properties of the soil solution 11 in the reaction chamber 5 by, for example, absorptiometry, and analyzes the soil components contained in the soil solution 11 .
The analyzer 14 includes a light emitter 15 , a light receiver 16 and a controller 17 . The reaction vessel 1 is arranged between the light emitting section 15 and the light receiving section 16 . The light emitting unit 15 irradiates the reaction chamber 5 with light according to a command from the control unit 17 . Light emitted from the light emitting unit 15 passes through the reaction chamber 5 . The light transmitted through the reaction chamber 5 is received by the light receiving section 16, and the light receiving section 16 measures the transmission amount of the received light. This light transmission amount is sent from the light receiving section 16 to the control section 17 . The control unit 17 calculates the absorbance of the soil solution 11 in the reaction chamber 5 based on the amount of transmitted light output from the light receiving unit 16, and calculates the concentration of the soil component in the soil solution 11 from the calculated absorbance. . As a result, the amount of soil components in the soil solution 11 can be measured (analyzed).

The analysis device 14 includes a transfer device (not shown), and the reaction vessel 1 can be transferred in the first direction A1 and the second direction A2 by the transfer device. When analyzing the soil solution 11 injected into the section 3 of 1, the soil solution 11 accommodated in the first reaction chamber 5A to the sixth reaction chamber 5F is analyzed by transferring the reaction container 1 in the second direction A2. do. Also, after the analysis of the first section 3A is completed, the reaction vessel 1 is moved in the first direction A1 to analyze the soil solution 11 injected into the second section 3B. Below, analyze in the same way up to the fifth section 3E.

FIG. 6 shows a modification of the reaction vessel 1 according to the first embodiment. In the reaction container 1 according to this modified example, the container body 2 has a main portion 2A having a reaction chamber 5 and a soil solution supply channel 6, and a lid portion 2B detachably provided on the upper portion of the main portion 2A. When the lid portion 2B is removed from the main portion 2A, the upper surface of each reaction chamber 5 in each section 3 can be opened (opened). Therefore, in the reaction container 1 according to this modified example, the reaction reagent can be introduced into each reaction chamber 5 after the soil solution 11 is injected.

FIG. 7 shows the reaction vessel 1 according to the second embodiment. A container body 2 of the reaction container 1 according to the second embodiment is formed in a disc shape. A plurality of sections 3 are arranged side by side in the circumferential direction R1 of the container body 2 . In each section, a plurality of reaction chambers 5 are arranged side by side in the circumferential direction R1 on the outer peripheral side of the container body 2 .
In each section, the injection part 4 is provided on the inner peripheral side of the container body 2 . Therefore, the injection part 4 in the reaction container 1 is arranged in the container main body 2 in the circumferential direction R1.

The soil solution supply channel 6 has a first supply channel 8 communicating with the injection part 4 and a plurality of second supply channels 9 branched from the first supply channel. The first supply passage 8 includes a first passage 8A extending radially outward from the injection portion 4, and a second passage 8B communicating with the radially outer end side of the first passage 8A and extending in the circumferential direction R1 of the container body 2. have A plurality of second supply paths 9 (first path 9A to sixth path 9F) communicate the second path 8B with each reaction chamber 5 (first reaction chamber 5A to sixth reaction chamber 5F).

Other configurations are similar to those of the first embodiment.
In this second embodiment, when the soil analysis of the soil solution 11 injected into the reaction container 1 is performed by the analysis device 14 shown in FIG. Then, the soil solution 11 in the reaction chamber 5 is analyzed sequentially by rotating the reaction vessel 1 .
8 and 9 show the reaction vessel 1 according to the third embodiment. In the reaction vessel 1 according to the third embodiment, a cylindrical vessel body 2 is vertically divided into three sections, each of which is a section 3 . In other words, the reaction vessel 1 is configured by stacking a plurality of disk-shaped sections 3 (first section 3A to third section 3C) in the vertical direction.

A plurality of reaction chambers 5 (first reaction chamber 5A to sixth reaction chamber 5F) in each section 3 are arranged side by side in the circumferential direction R2 on the outer peripheral side of the section 3 . A first supply channel 8 of the soil solution supply channel 6 in each section 3 is formed in a circular shape extending in the circumferential direction R2 of the section 3 . The first feed channel 8 of the first section 3A is larger in diameter than the first feed channel 8 of the second section 3B, and the first feed channel 8 of the second section 3B is larger than the first feed channel 8 of the third section 3C. Larger in diameter. The injection part 4 in each section 3 extends upwards from the first feed channel 8 . The second supply passage 9 (first passage 9A to sixth passage 9F) of each section extends from the first supply passage 8 in the radial direction of the section 3 and corresponds to the reaction chamber 5 (first reaction chamber 5A to sixth reaction chamber 5A). It communicates with the chamber 5F).

A reaction vessel 1 according to the third embodiment has a first communication path 18 and a second communication path 19 . A first communication passage 18 is formed through the first section 3A and communicates with the injection portion 4 of the second section 3B. Therefore, the soil solution is injected through the first communication passage 18 into the injection portion 4 of the second section 3B. The second communication passage 19 is formed through from the first section 3A to the second section 3B and communicates with the injection portion 4 of the third section 3C. Therefore, the soil solution is injected through the second communication path 19 into the injection part 4 of the third section 3C.

The first section 3A to third section 3C are separably joined to each other. When the soil solution injected into the reaction vessel 1 according to the third embodiment is subjected to soil analysis, the first section 3A to the third section 3C are separated from each other.
The reaction vessel 1 of this embodiment has the following effects.
The reaction vessel 1 includes an injection part 4 for injecting a soil solution 11 containing soil components, and a plurality of reaction reagents 7 for reacting the soil components in the soil solution 11 injected from the injection part 4 with the reaction reagents 7. A plurality of sections 3 each having a chamber 5 and a soil solution supply channel 6 for supplying the soil solution 11 injected from the injection part 4 to each reaction chamber 5 are provided.

According to this configuration, by injecting a different soil solution 11 to be analyzed into each section 3, component analysis of a plurality of soils to be analyzed can be performed. As a result, analysis efficiency can be improved.
A plurality of reaction chambers 5 in each section 3 are chambers for reacting different soil components.

According to this configuration, it is possible to perform a plurality of component analyzes of a plurality of soils to be analyzed.
Each section 3 also has an indicator 10 for associating the injected soil solution 11 .
With this configuration, the section 3 and the soil solution 11 injected into the section 3 can be associated.

Further, the plurality of sections 3 are arranged side by side in a first direction A1, and the plurality of reaction chambers 5 are arranged side by side along a second direction A2 intersecting the first direction A1 and the vertical direction. , the soil solution supply path 6 includes a first supply path 8 that is spaced apart from the plurality of reaction chambers 5 in the first direction A1 and formed along the second direction A2, and a first supply path 8 It has a plurality of second supply channels 9 which are channels connecting the reaction chambers 5 and are provided for each of the reaction chambers 5 .

According to this configuration, the reaction vessel 1 having a plurality of sections 3 can be easily formed.
Further, a disk-shaped container body 2 in which a plurality of sections 3 are arranged in the circumferential direction R1 is provided, and a plurality of reaction chambers 5 in each section 3 are arranged in the circumferential direction R1 on the outer peripheral side of the container body 2, The injection part 4 of each section 3 is arranged side by side in the circumferential direction R<b>1 on the inner peripheral side of the container body 2 .

This configuration also facilitates formation of the reaction vessel 1 having a plurality of sections 3 .
Also, a plurality of sections 3 may be provided in a layered manner in the vertical direction.
A plurality of reaction chambers 5 in each section 3 contain reaction reagents 7 corresponding to soil components to be analyzed, and each reaction chamber 5 contains reaction reagents 7 corresponding to different soil components. Each 3 contains a reaction reagent corresponding to the same soil component.

According to this configuration, the same component analysis can be performed for a plurality of component analyzes of a plurality of soils to be analyzed.
Although one embodiment of the present invention has been described above, it should be considered that the embodiment disclosed this time is illustrative in all respects and is not restrictive. The scope of the present invention is indicated by the scope of the claims rather than the above description, and is intended to include all modifications within the scope and meaning equivalent to the scope of the claims.

2 container body 3 section 4 injection part 5 reaction chamber 6 soil solution supply channel 7 reaction reagent 8 first supply channel 9 second supply channel 10 indicator part 11 soil solution A1 first direction A2 second direction R1 circumferential direction

Claims (4)

an injection section for injecting a soil solution containing soil components;
a plurality of reaction chambers for reacting the soil components in the soil solution injected from the injection part with the reaction reagent;
a plurality of sections having a soil solution supply path that supplies the soil solution injected from the injection part to each of the reaction chambers;
A reaction vessel for soil analysis, wherein the plurality of sections are vertically stacked. 2. The reaction container for soil analysis according to claim 1, wherein the plurality of reaction chambers in each section are chambers for reacting different soil components. 3. The reaction vessel for soil analysis according to claim 1 or 2, wherein each section has an index part for associating with the injected soil solution. The reaction container for soil analysis according to any one of claims 1 to 3, wherein each section is formed in a disc shape.

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