KR20130076562A - Verification apparatus for ammonium gas and nitrite gas of soil for agriculture - Google Patents

Abstract

PURPOSE: An inspection apparatus of ammonium gas and nitrite gas in soil for agriculture is provided to visually identify chromogenic reaction in each impinger and to immediately determine the presence of toxic gas such as ammonium gas or nitrite gas in the gas released from soil. CONSTITUTION: An inspection apparatus of ammonium gas and nitrite gas in soil for agriculture is stably mounted around crops which need gas inhalation. The apparatus comprises: a housing (100) with an inlet and an outlet which are penetrated for supplying inhaled soil gas to an impinger or discharging the soil gas after the soil gas passes through the impinge; a soil gas inlet part for inhaling gas from the soil and transfers into the inside of the housing; a soil gas dispersion part which controls the movement path of the soil gas to confirm the presence of ammonium gas or nitrite gas in the soil gas; a chromogenic part (400) for detecting the presence of ammonium gas or nitrite gas by allowing the soil gas to pass through a reagent in the impinge; and a power supply unit which supplies electric power for driving a vacuum pump for inhaling the soil gas. [Reference numerals] (AA,DD) HNO_2 inhalation; (BB,CC) HNO_2 discharge

Description

Ammonia Gas and Nitrite Gas Assay Device in Agricultural Soil {VERIFICATION APPARATUS FOR AMMONIUM GAS AND NITRITE GAS OF SOIL FOR AGRICULTURE}

The present invention relates to an ammonia gas and nitrite gas assay device, and more particularly, a predetermined time after forming a suction hole having a predetermined size in the soil to measure the gas and a funnel of a fallopian tube in close contact with the suction hole. While inhaling the air containing the gas discharged from the soil, the aspirated air is dispersed and supplied to the impinger with the reagent for ammonia gas assay and the impinger with the nitrite gas assay reagent. While visually confirming the color reaction, it is possible to immediately determine whether harmful gases such as ammonia gas or nitrite gas exist in the gas emitted from the soil, thereby minimizing crop damage caused by harmful gas. Ammonia gas and nitrite gas assay device in soil.

In general, if a large amount of nitrogen fertilizer is supplied while growing crops in soil or mixed with an alkaline fertilizer such as lime or high soil fertilizer, the soil becomes alkaline and nitrogen is used to generate ammonia gas (NH ₃ ). do.

In addition, when a large amount of organic materials such as less compost or poultry is applied, ammonia gas generated in the process of the organic material is collected to alkalinize the soil and generate ammonia gas.

The ammonia gas generated in this way is volatilized into the atmosphere through the soil pores. If the ammonia gas comes into contact with the roots of the roots extending to the soil during the soil pores, the weak parts of the roots are damaged. In particular, root hairs are the first to be disturbed, and as the concentration of gases that do not diffuse into the atmosphere in vinyl houses or tunnels increases, the crops are absorbed and damaged.

As such, when the ammonia gas is absorbed from the leaves, they enter the plant through the pores of the crop leaves or the gaps of the epidermis and deprive oxygen, which causes chlorophyll or pigment to be destroyed and discolored. If the damage is minor, black spots will occur. However, if the damage is severe, white spots will appear between the leaf veins.

In addition, when ammonia gas is absorbed from the roots, the root hair tissue dies and the root hair becomes thinner than normal, and ammonia gas penetrates into the root tissue, thereby inhibiting water absorption from the plant roots. The damage caused by ammonia gas from the roots causes yellowing on the leaves of the ground or brown spots between the leaf veins. When the concentration of ammonia gas in the soil is high, the absorption of water from the roots is strongly inhibited. These withered brown spots can appear and eventually die.

In addition, the organic matter applied in the soil is decomposed by the microorganisms to be ammonia. Thus, the ammonia obtained from the organic matter or the ammonia applied in the soil is changed to nitrite (NO ₂ ) by nitrite bacteria, and the nitrite is again converted to nitric acid (Nitrate) by nitrate bacteria. HNO ₃ ). However, when the amount of nitrogen fertilization is large, the action of nitrate bacteria that convert nitrite to nitric acid does not reach, and nitrite remains in the soil. Nitric acid is also converted to nitrous acid by nitrate reducing bacteria. At this time, if the soil is neutral, nitrite is not gasified, but when the soil is acidic or the acid content of the soil is high and acidified, the soil acidity (pH) is lowered to 5.0 or less, so that nitrite gas (NO ₂ ) is generated a lot.

In addition, as the temperature rises, nitric acid is rapidly generated and gasified to flow out through the soil pores and volatilize, but damage to crops when gas cannot be diffused into the atmosphere by a vinyl house, tunnel, or vinyl coating.

Thus, nitrite gas causes scars on the edges or leaf veins of crops. When the cells collapse due to these scars, small, necrotic parts of white to yellowish brown color are formed. The whole may become white.

As the most basic method to prevent damage caused by harmful gases such as ammonia gas and nitrite gas generated in the soil, the laboratory analysis to keep the proper fertilization rate determined by crop and cultivation method by conducting soil test after soil sample and preparation every year. A method is mentioned.

However, most farms carry out conventional fertilization by experience, so they are often overburdened, and therefore, salt accumulation in the soil is intensifying. In addition, overuse and misuse of fertilizers is a common occurrence in most farms.

For example, although organic substances such as compost contain a large amount of fertilizer components such as nitrogen (N), phosphoric acid (P), and kali (K), after sufficiently applying compost, nitrogen (N) and phosphoric acid ( P) and Kali (K) are often used additionally. In other words, fertilizers are frequently overused by the application of chemical fertilizers without any consideration of fertilizer components in the compost. In addition, it is easy to generate harmful gases such as giving fertilizer at a time without dividing a large amount of fertilizer according to the growing season, applying organic substances that are not completely homeless to the soil, or when the acidity (pH) of the soil is 5.0 or above 7.0. Conditions vary widely.

In addition, crop damage symptoms caused by nitrous acid gas or ammonia gas, which are nitrogen gas generated in the soil, are very similar to wilting disease, vine blight disease, late blight, and wearing disease. Therefore, the need for a tester (gas collector) that can determine the generation of harmful gas from the soil for the accurate diagnosis is increasing.

However, conventionally, in order to measure the concentration of ammonia gas and nitrite gas, a disposable detection tube was used in the field, or the gas was collected by sampling with a syringe or the like and analyzed using an analyzer such as gas chromatography in a laboratory. .

At this time, the use of the detection tube is mainly used in factory chimneys or contaminated places, which is a useful method of measuring the gas concentration, and thus, there was a significant difference from directly collecting and testing gas generated in the soil during crop cultivation.

In addition, the minimum damage concentration at which crop damage occurs is different for each crop, but in general, the minimum ammonia gas concentration causing damage to crops is 10ppm or more (concentration range in a normal vinyl house: 0.01 ~ 2.14ppm), nitrous acid gas concentration It is known as more than 5ppm (concentration range in normal vinyl house: 0.01 ~ 0.03ppm).

In addition, in the related art, as disclosed in Korean Patent Publication No. 10-0497514, an air particulate collecting device for collecting particulates suspended in air, analyzing them in an impinger, and measuring a collecting environment has been proposed.

However, since the minimum concentration of harmful gases that can cause damage to crops is very small as described above, the presence of harmful gases that are blocking the voids in the soil after this amount of harmful gases has diffused from the soil into the air. There was a problem that it is difficult to accurately measure abundance.

Accordingly, in the past, a person directly collected the air discharged from the soil at the field where the crop was grown, and analyzed the existence of the gas present in the air. However, in this case, a person has to collect the air directly. There was a problem that required this, and because the force is different for each person who collects air, there is a problem that it is difficult to secure the stability of the test, such that the collection amount is different and may not be able to secure enough air for the analysis of harmful gases. .

In addition, conventionally, in order to check the concentration of harmful gas present in the air collected by a person, it was necessary to move to a laboratory that can analyze the collected air.

The problem to be solved by the present invention is to form a suction hole of a certain size in the soil to measure the gas and to close the fallopian-shaped funnel (funnel) in close contact with the suction hole air containing the gas discharged from the soil for a certain time By dispersing and supplying the aspirated air to an impinger with an ammonia gas assay reagent and an impinger with a nitrite gas assay reagent, thereby visually confirming the color reaction at each impinger. The present invention provides an ammonia gas and nitrite gas assay device in agricultural soil, which enables the site to immediately determine whether harmful gas such as ammonia gas or nitrite gas is present in the gas.

Ammonia gas and nitrous acid gas assay device in agricultural soil for solving the above problems,

A housing in which a suction port and a discharge port are penetrated to be stably installed around the crop to be inhaled in the soil and form an overall appearance of the apparatus, and the suctioned soil gas is supplied to the impinger or passed through the impinger and then discharged again; A soil gas inlet unit for sucking gas from the soil and transferring the gas into the housing; A soil gas dispersion unit configured to control a movement path of the soil gas to determine whether ammonia gas or nitrite gas is present in the soil gas delivered to the soil gas inlet; A color reaction unit that tests the presence of ammonia gas or nitrite gas while passing the reagent contained in the impinger through the soil gas delivered through the path controlled by the soil gas dispersion unit; And it characterized in that it comprises a power supply for supplying power for driving a vacuum pump for suction of soil gas.

At this time, the soil gas inlet,

A suction funnel made of a wide fallopian tube shape in order to suck the gas in direct contact with the soil; A tubing tube for supplying soil gas sucked through the suction funnel to the housing; One end of the tubing pipe is coupled to the soil gas inlet formed through the housing to supply soil gas into the housing; And a vacuum pump positioned in the housing and providing a suction force of the soil gas through the suction funnel.

In addition, the soil gas dispersion unit,

A nitrite gas (HNO ₂ ) control unit for adjusting the air supplied to the soil gas inlet opening or blocking the path to the first impinger and the air supplied to the soil gas inlet to the second impinger Flow control unit for controlling the movement path of the soil gas consisting of ammonia gas (NH ₃ ) control unit for controlling to open or block the supplied path; And a nitrous acid gas supply pipe through which the soil gas introduced through the soil gas suction port is supplied to the first impinger, a nitrite gas discharge pipe discharged after passing through the first impinger, and the soil introduced through the soil gas suction port. And a suction air moving tube including ammonia gas supply pipe supplied with gas to the second impinger, and ammonia gas discharge pipe discharged after passing through the second impinger.

In addition, the color reaction unit,

One end is connected to the nitrite gas supply pipe, and an imidazole solution is stored as a reagent for nitrite gas assay to collect nitrite gas, a sulfanilamide solution is added and mixed, and the NED reagent is again mixed. A first impinger for assaying nitrite gas by judging whether it is colored pink after the addition; And a second impinger connected at one end to the ammonia gas supply pipe and storing a 2% boric acid as a reagent for ammonia gas assay and determining whether the color is colored blue by ammonia gas to test ammonia gas. Characterized in that the configuration.

The present invention forms a suction hole of a predetermined size in the soil to measure the gas and close the fallopian tube-shaped funnel (funnel) in close contact with the suction hole while sucking the air containing the gas discharged from the soil for a predetermined time, The supplied air is dispersed and supplied to an impinger with an ammonia gas assay reagent and an impinger with a nitrite gas assay reagent, thereby visually confirming the color reaction at each impinger, while ammonia gas is released from the soil. In addition, it is possible to immediately determine whether there is a harmful gas such as nitrous acid gas in the field.

In addition, the present invention is easy to carry whether the generation of ammonia gas and nitrite gas, which are harmful gases generated when cultivating crops at agricultural production sites and damaging crops, and through a suction funnel directly contacting the gas discharged from the soil to the soil. While continuously inhaling for a certain time, it is possible to easily check the presence of harmful gases on the site, and there is an effect that can quickly identify the gas damage that may occur from the soil.

In addition, since the present invention can quickly determine the presence of harmful gases in the soil, when the generation of harmful gases in the soil is confirmed quickly prescribed a method for improving the soil to prevent farm damage in advance or find early Therefore, it is possible to contribute to the increase of farm household income by improving the soil.

1 is a perspective view of an ammonia gas and nitrite gas assay apparatus in agricultural soil according to the present invention.
Figure 2 is a front photograph of the ammonia gas and nitrite gas assay device in agricultural soil according to the present invention.
Figure 3 is a rear view of the ammonia gas and nitrite gas assay device in agricultural soil according to the present invention.
Figure 4 is a rear view of the ammonia gas and nitrite gas assay device in agricultural soil according to the present invention.
5 is a plan view of the ammonia gas and nitrite gas assay device in agricultural soil according to the present invention.
Figure 6 is a side view of the ammonia gas and nitrite gas assay device in agricultural soil according to the present invention.
Figure 7 is a photograph of the internal configuration of the ammonia gas and nitrite gas assay device in agricultural soil according to the present invention.
Figure 8 is a photograph showing that the nitrite gas in the soil gas in accordance with the present invention is the first impinger color developed.
Figure 9 is a photograph showing that the presence of ammonia gas in the soil gas in accordance with the present invention the color of the reagent of the second impinger.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 is a perspective view of an ammonia gas and nitrite gas assay device in agricultural soil according to the present invention, Figure 2 is a front view of the ammonia gas and nitrite gas assay device in agricultural soil according to the invention, Figure 3 according to the present invention 4 is a rear view of the ammonia gas and nitrite gas assay device in agricultural soil, and FIG. 4 is a rear view of the ammonia gas and nitrite gas assay device in agricultural soil according to the present invention.

1 to 4, the ammonia gas and nitrite gas assay device in the agricultural soil according to the present invention, the housing 100 which is stably installed around the crop to inhale the gas in the soil and forms the overall appearance of the device And a soil gas inlet 200 that sucks gas from the soil and delivers it into the housing, and a path of movement of soil gas to determine whether ammonia gas or nitrite gas is present in the soil gas delivered to the soil gas inlet. Soil gas dispersion unit for controlling the 300, and the color reaction unit to test the presence of ammonia gas or nitrite gas while passing the reagents contained in the impinger to the soil gas delivered through the path controlled in the soil gas dispersion unit 400, and the collection time for setting the continuous collection time of the soil gas sucked through the soil gas inlet It includes a setting unit 500, and a power supply unit 600 for supplying power for driving a vacuum pump for suction of soil gas.

The housing 100 is provided with a plurality of equipment, such as a vacuum pump and suction air moving tube therein, and is composed of a steel plate such as stainless steel having excellent durability against external moisture or soil. In addition, the housing 100 is formed through the soil gas inlet 230 constituting the soil gas inlet portion, the soil gas delivered through the suction air moving pipe installed in the housing supplied to the impinger or passed through the impinger Afterwards, the inlet and outlet are formed to be discharged again.

The soil gas inlet 200 is a suction funnel 210 having a wide end of a trumpet tube shape to directly in contact with the soil to suck the gas, and a tubing tube for supplying the soil gas sucked through the suction funnel to the housing ( 220, and one end of the tubing pipe is coupled to the soil gas inlet 230 for supplying soil gas into the housing, and the vacuum pump 240 is located in the housing to provide the suction force of the soil gas through the suction funnel It is configured to include.

At this time, it is preferable to form a suction hole perforated to a predetermined size in the soil, and to allow the end of the suction funnel 210 to surround the suction hole formed in the soil so that sufficient soil gas can be sucked.

The suction hole formed in the soil is formed by drilling at a depth of about 10 to 15 cm at a position approximately 10 cm away from the crop, so as to determine whether the crop is affected by the harmful gas, located in the upper layer of the soil and radiates to the outside In addition to the noxious gas just before the end, the noxious gas present at a depth of 10-15 cm that can be absorbed by the roots of crops can be tested.

The tubing tube 220 is a tube connecting the suction funnel 210 and the soil gas suction port 230, and preferably formed of a flexible material to allow free movement of the suction funnel.

In addition, the vacuum pump 240 promotes the suction of soil gas in the suction funnel by generating a suction force for sucking the soil gas, while the suction power is continuously driven for a time set by the timer provided in the collection time control unit. It is desirable to be configured to produce.

The soil gas dispersion unit 300 supplies the soil gas supplied to the soil gas suction port 230 to the first impinger 410 for nitrite gas assay or to the second impinger 420 for ammonia gas assay. Flow control unit 310 for controlling the movement path of the soil gas to be supplied, and the suction air moving pipe for supplying the soil gas sucked along the movement path controlled by the flow control unit to the first or second impinger respectively ( 320).

At this time, the flow control unit 310 as shown in Figures 1 and 2 nitrite gas to adjust to open or block the air supply to the soil gas inlet 230 is supplied to the first impinger (HNO ₂ ) control unit 311, and the ammonia gas (NH ₃ ) control unit 312 to control to open or block the path to which the air supplied to the soil gas inlet 230 is supplied to the second impinger It is configured to include. At this time, the nitrite gas control unit 311 and the ammonia gas control unit 312 may be configured to automatically open and close the path, as well as to open and close each path while the worker to collect and test the soil gas by hand. It may be configured to.

In addition, both the nitrite gas control unit 311 and the ammonia gas control unit 312 are opened, so that the inhaled soil gas is uniformly supplied to the first and second impingers so that simultaneous nitrite gas and ammonia gas can be simultaneously assayed. Of course you can.

In addition, the suction air moving pipe 320 is a nitrite gas supply pipe 321 is supplied with the soil gas introduced through the soil gas inlet to the first impinger, as shown in Figs. The nitrite gas discharge pipe 322 discharged after passing through the first impinger, and the ammonia gas supply pipe 323 to which the soil gas introduced through the soil gas inlet are supplied to the second impinger, and the second impinger After passing through the ammonia gas discharge pipe 324 is configured.

Accordingly, the nitrous acid gas discharge pipe 322 and the ammonia gas discharge pipe 324 are connected to the ventilation fan 330 provided in the housing to discharge the soil gas, which has been tested in the first and second impingers, out of the housing. Let's go.

The color reaction unit 400 has a first end connected to the nitrite gas supply pipe 321 and a first impinger 410 in which a reagent for nitrite gas assay is stored, and one end to the ammonia gas supply pipe 323. And a second impinger 420 connected and storing reagents for ammonia gas assay.

In this case, the first impinger 410 and the second impinger 420 is formed of a transparent material so that the operator can easily visually recognize the color reaction by the harmful gas present in the soil gas, the housing ( It is preferable to install in front of the 100).

In addition, an imidazole solution is stored in the first impinger 410 as a reagent for determining the presence of nitrite gas, and the boric acid for determining whether ammonia gas is present in the second impinger 420. (Boric acid) is stored.

At this time, in order to determine the presence or absence of nitrite gas in the first impinger 410, the nitrite gas is collected in the imidazole solution, added by dissolving a sulfanilamide solution, and then shaken to mix the solution and the NED reagent. Should be added again to observe the color development.

Accordingly, the imidazole solution is prepared by dissolving 6.81 g of the reagent in 800 ml of distilled water and adjusting the pH to 7.5 using hydrochloric acid (HCl), and making 0.1 M Imidazole solution thus prepared. Diluted by fold to prepare a 0.01M Imidazole solution to use (5ml / 1 time).

In addition, the sulfanilamide solution is prepared by dissolving 10 g of a reagent in 600 ml of distilled water containing 100 ml of concentrated hydrochloric acid (HCl) and preparing 1 liter (1 ml / 1 time). In addition, the NED is used in a small amount as a powder form.

As such, a 0.01 M imidazole solution having a high basic pH (pH7.5) is stored in the first impinger 410 to collect nitrite gas, and 1 ml of a strong acid sulfanylamide solution is added thereto, followed by reaction with a strong acid. A small amount of NED, which is a reagent, is used to observe color development, and the higher the concentration of nitrous acid dissolved, the color turns red. Done.

In addition, 2% boric acid (Boric acid) stored to determine the presence of ammonia gas in the second impinger 420 is dissolved 20g of boric acid (H ₃ BO ₃ ) in distilled water containing 5ml mixed indicator. After 1L mess up, use (5ml / 1 times). At this time, it is preferable to adjust the pH to 4.5 with H ₂ SO ₄ or NaOH solution (5 ml / 1 time).

As such, when ammonia gas is dissolved in the strong acid (pH4.5) 2% boric acid solution (bolic acid) stored in the second impinger 420, as shown in FIG. Since the color gradually changes to blue, the presence of ammonia gas in the soil gas is determined by observing such a change in color.

In addition, when the reagent used in the measurement is discolored, the first impinger 410 is already present in order to change the reagent to the original colorless color so that it is easy to determine whether discoloration by nitrite gas or ammonia gas in the subsequent measurement. It is preferable to add about 5 ml of the doazole solution and to supplement the second impinger 420 by adding about 5 ml of the boric acid solution.

The collection time setting unit 500 is a timer for automatically or manually setting the collection time for sucking the soil gas by driving the vacuum motor after fixing the suction funnel in the suction hole perforated in the soil, and the time set in the timer It is composed of a microcomputer for controlling to continue to drive the vacuum motor for a while and to stop the drive of the vacuum motor after a lapse of time.

At this time, the air sucked through the suction funnel 210 is a gas in the soil, that is, unlike the conventional trapping device that previously collected the gas in the air, that is to move between the pores of the soil for a long time, and gradually volatilized into the air Since it is intended to test for the presence of harmful gases, a short time of inhalation prevents the capture of a sufficient amount of harmful gases for the assay. Accordingly, it is preferable to continuously inhale the soil gas for a predetermined time, for example, 10 minutes, by a timer provided in the collection time setting unit, so that it is possible to capture a sufficient amount of harmful gas for the harmful gas assay.

The power supply unit 600 is configured to include a battery capable of supplying power for driving a vacuum pump or a timer provided in the ammonia gas and nitrite gas assay apparatus according to the present invention. In this case, the power supply may be configured as a rechargeable battery to improve the convenience of movement of the assay device, as well as a power cord for stable and continuous power supply or battery charging.

In addition, the ammonia gas and nitrous acid gas assay device in the agricultural soil according to the present invention, as shown in Figure 5 and 7, do not use a long-term (for example, six months or more) power supply, or after charging the power cord When left unplugged while the power is connected, the discharge control panel 700 to prevent the discharge to prevent the battery from being discharged by itself, and the control switch for controlling the activation of the vacuum pump, etc. by the consumption of power It is preferably configured to further include (710).

The ammonia gas and nitrite gas assay device in the agricultural soil according to the present invention thus constructed freely moves the agricultural production site so that the presence of ammonia gas and nitrite gas can be immediately confirmed by the soil gas sucked from the soil around the crop. do.

In addition, the worker can freely set the collection time of the soil gas by a timer provided on the front of the housing. Thus, by ensuring a sufficient collection time of the harmful gas discharged from the soil, the presence of noxious gas such as ammonia gas or nitrite gas can be determined. More accurate and stable tests can be made.

In addition, the ammonia gas and nitrite gas assay device in the agricultural soil according to the present invention can be provided with a soil gas dispersion unit to set the movement path of the inhaled soil gas, the intensive collection of soil gas according to the type of gas to be tested This enables intensive testing of specific hazardous gases.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100-housing 200-soil gas inlet
210-Suction Funnel 220-Tubing Tube
230-Soil gas inlet 240-Vacuum pump
300-soil gas dispersion unit 310-flow control unit
311-nitrous acid gas regulator 312-ammonia gas regulator
320-Suction air moving pipe 321-Nitrite gas supply pipe
322-nitrous acid gas outlet 323-ammonia gas supply line
324-Ammonia gas outlet 330-Ventilation fan
400-Color Reaction Unit 410-First Impinger
420-Second Impinger 500-Capture Time Adjuster
600-Power supply 700-Discharge prevention control
710-control switch

Claims (5)

A housing in which a suction port and a discharge port are penetrated to be stably installed around the crop to be inhaled in the soil and form an overall appearance of the apparatus, and the suctioned soil gas is supplied to the impinger or passed through the impinger and then discharged again;
A soil gas inlet unit for sucking gas from soil and transferring the gas into the housing;
A soil gas dispersion unit configured to control a movement path of the soil gas to determine whether ammonia gas or nitrite gas is present in the soil gas delivered to the soil gas inlet;
A color reaction unit that tests the presence of ammonia gas or nitrite gas while passing the reagent contained in the impinger through the soil gas delivered through the path controlled by the soil gas dispersion unit; And
Ammonia gas and nitrite gas assay device in the agricultural soil, characterized in that it comprises a power supply for supplying power for driving a vacuum pump for suctioning the soil gas. The method of claim 1,
The soil gas inlet,
A suction funnel made of a wide fallopian tube shape in order to suck the gas in direct contact with the soil;
A tubing tube for supplying soil gas sucked through the suction funnel to the housing;
One end of the tubing pipe is coupled to the soil gas inlet formed through the housing to supply soil gas into the housing; And
Ammonia gas and nitrite gas assay device in agricultural soil, characterized in that it comprises a vacuum pump located in the housing to provide a suction force of the soil gas through the suction funnel. The method of claim 2,
The soil gas dispersion unit,
A nitrite gas (HNO ₂ ) control unit for adjusting the air supplied to the soil gas inlet opening or blocking the path to the first impinger and the air supplied to the soil gas inlet to the second impinger Flow control unit for controlling the movement path of the soil gas consisting of ammonia gas (NH ₃ ) control unit for controlling to open or block the supplied path; And
Sodium nitrite gas supply pipe through which the soil gas introduced through the soil gas suction port is supplied to the first impinger, nitrous acid gas discharge tube discharged after passing through the first impinger, and soil gas introduced through the soil gas suction port Ammonia gas and nitrite gas in the agricultural soil, characterized in that it comprises a suction air moving tube consisting of ammonia gas supply pipe is supplied to the second impinger and discharged after passing through the second impinger. Black device. The method of claim 3,
The color reaction unit,
One end is connected to the nitrite gas supply pipe, and an imidazole solution is stored as a reagent for nitrite gas assay to collect nitrite gas, a sulfanilamide solution is added and mixed, and the NED reagent is again mixed. A first impinger for assaying nitrite gas by judging whether it is colored pink after the addition; And
One end is connected to the ammonia gas supply pipe, and a second impinger that stores 2% boric acid as a reagent for ammonia gas assay and determines whether it is colored blue by ammonia gas to test ammonia gas. And ammonia gas and nitrite gas assay equipment in agricultural soils. 5. The method according to any one of claims 1 to 4,
A timer for automatically or manually setting a collection time for sucking soil gas by fixing a suction funnel to a suction hole perforated in the soil and driving a vacuum motor; And
The ammonia gas and nitrite gas assay in the agricultural soil, characterized in that it further comprises a capture time setting unit made of a microcomputer to continue to drive the vacuum motor for a time set in the timer and to stop the operation of the vacuum motor after the time elapsed. Device.

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