JP2015054880A - Soil treatment composition - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a soil treatment composition capable of making soil moisture percentage good by small water amount spray and exhibiting a good preventive effect of generation of water-repellent soil/improvement effect of the water-repellent soil.SOLUTION: There is provided a soil treatment composition containing the following (a) component used for prevention of generation of water-repellent soil and/or improvement of the water-repellent soil. (a) one or more kind selected from polyoxyethylene-polyoxypropylene-polyoxyethylene glycol and polyoxypropylene-polyoxyethylene-polyoxypropylene glycol having a number average molecular weight of 1500 to 3000 and a ratio occupied by polyethylene oxide in a molecule of over 10 mass%.

Description

The invention which this application discloses relates to the soil treatment composition used for generation prevention of water-repellent soil and / or improvement of water-repellent soil. Moreover, the invention which this application discloses relates to the soil treatment composition used for prevention of the dry spot which generate | occur | produces on a lawn, and / or improvement of the dry spot which generate | occur | produced on the lawn.
In detail, it is related with the soil treatment composition suitable for small amount of water dispersion.

  In the golf course green, which is a lawn, there is a local dry damage called a dry spot centering on the sand green, and the lawn dies as the symptom progresses. Therefore, it is a problem not to generate a dry spot.

  In dry spots, the soil is water-repellent and repels water even when sprinkled. In addition, since no capillary action occurs, there is no movement of water from the soil around the dry spot to the dry spot. For this reason, the moisture content of the soil in the dry spot becomes very low, the water necessary for the growth of the turf is not secured, and the turf is dead.

  The cause of soil water repellency is not necessarily clear, but it is thought to be due to soil consolidation, water spray unevenness, surface runoff of rainfall / water spray, excessive accumulation of organic matter, and the like. Regarding the accumulation of organic matter, sand is water-repellent by the attachment of oily substances produced by the debris from dried grass, dead leaves, stems, roots, and fungi in the soil. Although it has been pointed out that it is tinged, it has not been elucidated.

  In order to prevent dry spots, it is important not to dry the soil, but even in the soil before the occurrence of dry spots, once the soil moisture content decreases and water repellency is exhibited, water will permeate into the soil even if water is sprayed. It becomes difficult and sufficient effect of watering cannot be obtained.

  Therefore, it is thought that it is particularly important to improve the wettability of soil, and the following Patent Document 1, Patent Document 2, and the like disclose methods for preventing the occurrence of dry spots by spraying a specific mixture.

  In general, a method of improving the wettability of soil by spraying a material called a soil penetrating agent mainly containing a surfactant is used.

Japanese Patent Laid-Open No. 10-60437 JP 2002-20749 A

  When spraying materials such as soil penetrants, fertilizers and pesticides, tanks containing materials called tank cars, hoses for spraying, and cars equipped with pumps for feeding into hoses are often used. Named workers are required.

  In recent years, the number of golf course lawn managers has been decreasing, and it is required to perform a large amount of work with a limited number of people. Therefore, work efficiency is improved in each scene.

  As an example of material efficiency improvement, spraying with a passenger car (sprayer) for one person can be mentioned.

This sprayer is compact and lightweight, so it can work on the green and can spray a small amount of water of about 60 to 300 ml / m ² , reducing the spraying time compared to spraying with conventional tank trucks. it can. Therefore, it contributes greatly to efficiency and is rapidly spreading in golf courses nationwide.

  However, agricultural chemicals and fertilizers that are suitable for spraying small amounts of water have been put on the market, but soil penetrants are not yet available and rely on spraying with conventional tank cars.

That is, simply spraying a conventional soil penetrant at a high concentration and a small amount of water is not effective, and there is a risk of phytotoxicity (plant withering) to plants such as turf by the soil penetrant.
In addition to golf courses, farms, parks, schoolyards, and the like have demanded that small amounts of water of about 60 to 300 ml / m ^{2 be} applied, focusing on soil moisture content and chemical damage.

  This inventor repeated earnest research in order to develop the soil treatment composition with a high effect, even if sprayed with a small amount of water. As a result, polyoxyethylene-polyoxypropylene-polyoxyethylene glycol and polyoxypropylene-polyoxyethylene-poly having a number average molecular weight of 1500 to 3000 and a ratio of polyethylene oxide in the molecule exceeding 10% by mass. It has been found that at least one selected from oxypropylene glycol is useful. Furthermore, it discovered that 1 or more types of combined use chosen from polyoxyalkylene alkyl ether was also useful.

Based on the above findings, the present inventor has completed the invention disclosed by the present application. Therefore, it is set as the problem which should be solved to provide the soil treatment composition which exhibits a favorable effect by small amount of water dispersion.
Moreover, it is set as the problem which should be solved to provide the soil treatment method which uses the said soil treatment composition.

(First invention)
The first invention of the present application for solving the above-described problems is as follows.
It is a soil treatment composition containing the following component (a) used for preventing the generation of water-repellent soil and / or improving water-repellent soil.
(A) Polyoxyethylene-polyoxypropylene-polyoxyethylene glycol and polyoxypropylene-polyoxyethylene-poly having a number average molecular weight of 1500 to 3000 and a ratio of polyethylene oxide in the molecule exceeding 10% by mass One or more selected from oxypropylene glycol.

(Second invention)
The second invention of the present application for solving the above-described problems is as follows.
Furthermore, it is a soil treatment composition as described in 1st invention containing the following (b) component.
(B) One or more selected from polyoxyalkylene alkyl ethers.

(Third invention)
The third invention of the present application for solving the above problem is
It is a soil treatment composition as described in the 1st invention or 2nd invention whose cloud point of 1 mass% water dilution liquid is 20 degreeC or more.

(Fourth invention)
In order to solve the above problems, the fourth invention of the present application is:
The soil according to the second or third invention, wherein the mass-based content ratio of the component (a) and the component (b) is (a) component: (b) component = 9: 1 to 1: 9 It is a treatment composition.

(Fifth invention)
The fifth invention of the present application for solving the above-mentioned problems is
It is a soil treatment composition in any one of the 1st invention-the 4th invention sprayed at 300 ml / m < ² > or less.

(Sixth invention)
The sixth invention of the present application for solving the above-described problems is as follows.
A soil treatment method using the soil treatment composition according to any one of the first to fifth inventions.

The soil treatment composition disclosed in the present application can improve the soil moisture content by spraying a small amount of water, and exhibits a good water repellent soil generation prevention effect / water repellent soil improvement effect.
Moreover, the soil treatment method using the said soil treatment composition shows the generation | occurrence | production prevention effect of the favorable water-repellent soil / the improvement effect of water-repellent soil.

An example of wettability evaluation in an Example is shown. An example of the phytotoxicity evaluation of a test pot in an Example is shown.

  The invention disclosed in the present application will be described below including the best mode.

This application discloses the soil treatment composition containing the following (a) component used for generation prevention of water-repellent soil and / or improvement of water-repellent soil.
(A) Polyoxyethylene-polyoxypropylene-polyoxyethylene glycol (also referred to as POE-POP-POE block polymer) having a number average molecular weight of 1500 to 3000 and a ratio of polyethylene oxide in the molecule exceeding 10% by mass And at least one selected from polyoxypropylene-polyoxyethylene-polyoxypropylene glycol (also referred to as POP-POE-POP block polymer).

  The water-repellent soil is a soil in which when water is dripped onto the soil due to rainfall or watering, the soil is difficult to repel water and soak. Examples of the water-repellent soil include dry spots found on lawns, such as farms, road slopes, golf courses, parks, and schoolyards.

  The soil treatment composition disclosed in the present application is also preferably used for prevention of dry spots generated on lawn and / or improvement of dry spots generated on lawn.

  When the soil treatment composition disclosed in the present application is sprayed with a small amount of water on the soil where plants such as turf grow, it is considered that the soil treatment composition once adheres to plants such as turf. Then, it is thought that the soil treatment composition adhering to plants such as turf by watering or raining with a sprinkler or the like penetrates into the soil. Therefore, the soil treatment composition disclosed in the present application can maintain the growth of plants such as turf even if the soil treatment composition is first sprayed, and secondly has good permeability to soil. preferable.

The component (a) is a polyoxyethylene-polyoxypropylene-polyoxyethylene glycol and a polyoxypropylene having a number average molecular weight of 1500 to 3000 and a ratio of polyethylene oxide in the molecule exceeding 10% by mass -One or more selected from polyoxyethylene-polyoxypropylene glycol.
That is, the number average molecular weight is 1500 to 3000, and the proportion of polyethylene oxide in the molecule exceeds 10% by mass, and the number average molecular weight is 1500 to 3000. And the ratio for which the polyethylene oxide accounts in a molecule | numerator is 1 or more types chosen from polyoxypropylene-polyoxyethylene-polyoxypropylene glycol exceeding 10 mass%.

  The number average molecular weight of the component (a) is preferably 2000 to 3000. The number average molecular weight may be 2000-2600. On the other hand, when the number average molecular weight is outside the range of 1500 to 3000, it is considered that the effect of improving / maintaining the soil moisture content becomes insufficient by spraying a small amount of water on the soil.

  The proportion of polyethylene oxide in the component (a) molecule may be 10 to 60% by mass, or 10 to 40% by mass.

  The soil treatment composition disclosed in the present application may be used in combination with one or more selected from polyoxyalkylene alkyl ethers as the component (b) in addition to the component (a). It is considered that the permeability of the soil treatment composition to the soil can be improved by using the component (b) together with the component (a). Moreover, it is thought that the danger that a phytotoxicity by the (b) component may occur can be reduced.

  The polyoxyalkylene alkyl ether has a structure in which a polyoxyalkylene (polyoxyalkylene part) such as polyethylene glycol and a monovalent higher alcohol (alkyl group part) are bonded by an ether bond.

  Examples of the polyoxyalkylene part include polyoxyethylene, polyoxypropylene, and polyoxybutylene.

  The number of carbon atoms in the alkyl group moiety of the component (b) is not limited. From the viewpoint of soil wettability and prevention of chemical damage, the number of carbon atoms in the alkyl group is preferably 8-22, more preferably 8-18, more preferably 8-16, and 10-16. More preferably.

  When the soil treatment composition contains the component (a) and the component (b), the mass-based content ratio of both components is not particularly limited. From the viewpoint of controlling phytotoxicity, component (a): component (b) is preferably 9: 1 to 1: 9, more preferably 9: 1 to 4: 6, and 7: 3 to 4: 6. It is more preferable that the ratio is 4: 5 to 5: 4.

  The content of the component (a) and the component (b) at the time of spraying can be appropriately selected in consideration of the state of the soil. When the soil treatment composition contains the component (a), it is preferably 0.2 to 5.0% by mass, and more preferably 0.5 to 2.0% by mass. When the soil treatment composition contains the component (a) and the component (b), the content during the spraying is 0.2 to 5.0 mass in total of the component (a) and the component (b). %, And more preferably 0.2 to 1.0% by mass.

  The soil treatment composition which this application discloses may contain arbitrary components other than the said (a) component and (b) component. Examples of the optional component include water, nonionic surfactants not corresponding to the components (a) and (b), water-soluble polymers, agricultural chemicals, solvents, colorants, fragrances, chelating agents, salts, and the like.

  The cloud point of the soil treatment composition disclosed in the present application is not particularly limited. The cloud point may be 20 ° C. or higher, may be 30 ° C. or higher, and may be 40 ° C. or higher.

  In this application, the cloud point of a soil treatment composition is calculated | required using a 1 mass% water dilution liquid.

The soil treatment composition disclosed in the present application is preferably sprayed with a small amount of water. For small amount of water, specifically a 300 ml / ^{m 2} or less, often as 60~300ml / ^{m 2,} it may be a 60~200ml / ^{m 2.}

  The soil treatment composition which this application discloses can be manufactured by a normal method. The dilution rate of the soil treatment composition at the time of spraying can be appropriately selected in consideration of the state of the soil. The soil treatment composition may be sprayed after being diluted 100 to 300 times.

  As described above, the present application also discloses a soil treatment method using the soil treatment composition disclosed in the present application.

  Examples will be described below. The technical scope of the invention disclosed in the present application is not limited to the following examples.

[Test 1: Confirmation test of wettability of conventional product]
Sun Eagle SB-80 (manufactured by Sugimura Chemical Co., Ltd.) (hereinafter also referred to as SB-80), which is a soil treatment composition that has already been confirmed to have a dry spot preventing effect on golf course green in a conventional spraying method. And Sun Eagle SB-99 (manufactured by Sugimura Chemical Co., Ltd.) (hereinafter also referred to as SB-99).

-Test method-
(1) Sand was collected from a golf course green where dry spots were generated, and sieved to prepare test sand having a particle size of 1 mm or less.
(2) A plate with a hole for promoting drainage and fixing the filter paper was placed in a plastic pot having an inner diameter of 6 cm. Next, a filter paper was placed on the plate. Next, 50 g of test sand was put on the filter paper and the surface was leveled.
(3) 20 ml of SB-80 or SB-99 containing 0.2% by mass (diluted solution obtained by diluting the stock solution 500 times. The dilution medium is water. In the following tests, the dilution medium is the same.) 20 ml, test sand The solution was dropped from above and left for 5 minutes. Thereafter, when the liquid remained on the test sand surface, the liquid was discarded. As a control, a test was also conducted in which 20 ml of water was dropped onto the test sand.

-Evaluation-
The test sand in a plastic pot is turned over on a separately prepared tray, the filter paper is peeled off, and the ratio of the wet area to the total bottom area of the test sand (wet area / total bottom area × 100) is visually evaluated. (Wetability evaluation). An example of visual wettability evaluation is shown in FIG. The test was repeated three times, and the average value was evaluated.

  As a result, the wettability evaluation of SB-80 was 80%, and the wettability evaluation of SB-99 was 100%. On the other hand, in the control in which water was dropped, the water remained on the test sand, and the bottom surface of the test sand was not wet at all (wetability evaluation was 0%).

  As described above, there was a correlation between the dry spot prevention effect and the wettability evaluation in golf courses. That is, the soil treatment composition in which the effect of preventing dry spots on the golf course green showed high wettability in Test 1. In addition, the water (control) having no dry spot preventing effect on the golf course green had a poor wettability evaluation in Test 1.

  Therefore, it was considered that the test method using test sand can be used for screening raw material components, focusing on wettability.

[Test 2: Small water volume evaluation test]
-Test method-
(1) Sand was collected from a golf course green where dry spots were generated, and sieved to prepare test sand having a particle size of 1 mm or less.
(2) A plate with a hole for promoting drainage and fixing the filter paper was placed in a plastic pot having an inner diameter of 6 cm. Next, a filter paper was placed on the plate. Next, 50 g of test sand was put on the filter paper and the surface was leveled.
(3) 5 ml of SB-80 or SB-99 containing 0.5% by mass (diluted solution obtained by diluting the stock solution 200 times) was sprayed on the surface of the test sand in several sprays. The diluted solution was infiltrated into the surface.
(4) After the diluted solution penetrated the surface of the test sand, 15 ml of water was dropped on the test sand and left for 5 minutes. Thereafter, if water remained on the test sand surface, the water was discarded.

-Evaluation-
The wettability evaluation was determined by the same method as in Test 1 above. As a result, the wettability evaluation of SB-80 was 10%, and the wettability evaluation of SB-99 was 20%.

  From these results, it was considered that the conventional soil treatment composition is not suitable for small water application.

[Test 3: Screening test for ingredients]
The following raw materials (A) to (k) were used instead of the above SB-80 and SB-99.
Raw material (A): POE-POP-POE block polymer, cloud point 32 ° C. (number average molecular weight 2500, internal POE molecular weight 30% by mass).
Raw material (B): POP-POE-POP block polymer, cloud point 20 ° C. (number average molecular weight 2800, internal POE molecular weight 11 mass%).
Raw material (C): POE-POP-POE block polymer, cloud point 24 ° C. (number average molecular weight 2000, internal POE molecular weight 13 mass%).
Raw material (D): polyoxyalkylene branched decyl ether (carbon number of alkyl group: 10)
Raw material (E): polyoxyalkylene capryl ether (carbon number of alkyl group: 8).
Raw material (F): polyoxyalkylene lauryl ether (carbon number of alkyl group: 12).
Raw material (G): polyoxyalkylene cetyl ether (carbon number of alkyl group: 16).
Raw material (H): polyoxyalkylene oleyl ether (carbon number of alkyl group: 18).
Raw material (i): POE-POP-POE block polymer, cloud point 15 ° C. (number average molecular weight 3800, internal POE molecular weight 10% by mass)
Raw material (j): POE-POP-POE block polymer, cloud point 39 ° C. (number average molecular weight 1100, internal POE molecular weight 14% by mass)
Raw material (k): POP-POE-POP block polymer, cloud point 48 ° C. (number average molecular weight 3500, internal POE molecular weight 40% by mass)

-Test method-
The same as the test method described in Test 2 “Evaluation test for small amount of water”, except that each of the raw materials (A) to (k) is used as a 1% by mass containing liquid (diluted solution diluted 100 times). did.

-Evaluation-
For each of the raw materials (A) to (k), the wettability evaluation was obtained by the same method as in Test 1 above. as a result,
The wettability evaluation of the raw material (A) is 70%,
The wettability evaluation of the raw material (B) is 90%,
The wettability evaluation of the raw material (C) is 70%,
The wettability evaluation of the raw material (D) is 100%,
The wettability evaluation of the raw material (E) is 100%.
The wettability evaluation of the raw material (F) is 100%.
The raw material (G) has a wettability evaluation of 100%,
The wettability evaluation of the raw material (H) is 100%.
The wettability evaluation of the raw material (i) is 0%,
The wettability evaluation of the raw material (j) is 0%.
The wettability evaluation of the raw material (k) was 10%.

  As mentioned above, raw material (A)-raw material (H) were favorable wettability evaluation.

  One or more selected from POE-POP-POE block polymer and POP-POE-POP block polymer having a molecular weight of 1500 to 3000 and a ratio of polyethylene oxide in the molecule exceeding 10% by mass based on the evaluation results of wettability Moreover, it was thought that 1 or more types chosen from polyoxyalkylene alkyl ether was suitable for small water quantity spraying.

[Test 4: Small water content evaluation test of a mixture of the raw material (A) and the raw materials (D) to (H)]
The raw material (A) and the raw material (D) were mixed at a mass-based content ratio “raw material (A): raw material (D)” = 1: 1 to obtain a mixture (cloud point 59 ° C. of the mixture) .) The test was performed in the same test method as in Test 2 except that a 0.5% by mass solution (diluted solution diluted 200 times) of the mixture was used.
As a result of the test, the wettability evaluation of the mixture was 100%.

  Next, the raw material (A) and any one of the raw materials (E) to (H) were mixed at a mass-based content ratio of 1: 1 to obtain a mixture. The test was performed by the same test method as in Test 2 except that a 0.5% by mass solution (diluted solution diluted 200-fold) of each mixture was used.

  As a result of the test, the wettability evaluation of the mixture using the raw material (E) was 100%. The wettability evaluation of the mixture using the raw material (F) was 90%. The wettability evaluation of the mixture using the raw material (G) was 85%. The wettability evaluation of the mixture using the raw material (H) was 80%.

  One or more selected from POE-POP-POE block polymer and POP-POE-POP block polymer having a molecular weight of 1500 to 3000 and a ratio of polyethylene oxide in the molecule exceeding 10% by mass based on the evaluation results of wettability And a mixture of at least one selected from polyoxyalkylene alkyl ethers were considered suitable for low-water spraying. The smaller the number of carbon atoms in the alkyl group of the polyoxyalkylene alkyl ether, the higher the evaluation of wettability. It was thought that the number of carbon atoms in the alkyl group portion was more preferably 8-16.

[Test 5: Examination of dilution rate in spraying small amount of water]
-Test method-
(1) Sand was collected from a golf course green where dry spots were generated, and sieved to prepare test sand having a particle size of 1 mm or less.
(2) A plate with a hole for promoting drainage and fixing the filter paper was placed in a plastic pot having an inner diameter of 6 cm. Next, a filter paper was placed on the plate. Next, 50 g of test sand was put on the filter paper and the surface was leveled.
(3) The raw material (A) or a mixture obtained by mixing the raw material (A) and the raw material (D) at a mass-based content ratio of 1: 1 is used. The spray was sprayed on the surface of the test sand several times by spraying, and the diluted solution was infiltrated into the surface of the test sand.
(4) After the diluted solution permeated the surface of the test sand, the total amount of the diluted sprayed solution was adjusted to 20 ml, and water was added dropwise to the test sand and left for 5 minutes. Thereafter, if water remained on the test sand surface, the water was discarded.

-Evaluation-
The wettability evaluation was determined by the same method as in Test 1 above.

[Table 1]

Here, for reference, a conversion value is described for the spraying amount. This corresponds to a spray application amount of 2.5 ml = 60 ml / m ² . This corresponds to a spray application amount of 5.0 ml = 120 ml / m ² . This corresponds to a spray application amount of 10.0 ml = 240 ml / m ² . This corresponds to a spray application amount of 12.5 ml = 300 ml / m ² .

  From the above test results, if the amount of components dropped per unit area was the same, a high wettability effect was exhibited even if the dilution ratio changed.

[Test 6: Phytotoxicity test 1 using pot]
-Test method-
Put the sand in the pot, sow the seeds of bentgrass (variety name: Pencross), grow for 45 days in an artificial meteorograph set at 23 ° C, then grow the lawn (hereinafter, the pot equipped with the lawn was tested) (Also referred to as a pot) was subjected to the test.

0.5 g of a liquid containing 0.5% by mass of the raw material (A), the raw material (B) or the raw material (D) (diluted solution diluted 200 times) was sprayed from above the test pots, The spread rate was 0.6 g / m ² .

  After the spraying treatment, each test pot was grown for 3 days in an artificial meteor set to 30 ° C., and thereafter yellowing and browning of the leaves were evaluated.

-Evaluation-
The evaluation criteria were as follows.
No phytotoxicity: Leaves were not yellowed or browned.
Extremely mild: 0% <Turf yellowing / brown change area ≦ 10%.
Mild: 10% <turf yellowing / brown change area ≦ 25%.
Medium: 25% <Turf yellowing / brown change area ≦ 50%.
Severe: 50% <turf yellowing / brown change area ≦ 100%.

  Photographs of turf corresponding to these evaluations are shown in FIG. FIG. 2 is a photograph of no phytotoxicity, extremely mild, mild, moderate, and severe from the left side of the photograph. In addition, if there is no phytotoxicity and extremely mild evaluation, it is considered that it can withstand use in the field.

  As a result of the test, the test pot using the raw material (D) was evaluated as “medium”. On the other hand, the test pot using the raw material (A) and the raw material (B) was evaluated as “no phytotoxicity”.

  From the above results, it was considered that the POE-POP-POE block polymer and the POP-POE-POP block polymer are suitable for spraying a small amount of water from the viewpoint that chemical damage is less likely to occur.

[Test 7: Chemical hazard test 2 using pot]
The polyoxyalkylene alkyl ether whose phytotoxicity was confirmed in the test 6 was examined as to whether it can be used in combination with the raw material (A) or the raw material (B).

-Test 7-1-
A mass-based content ratio of “raw material (A): raw material (D)” = 9: 1, 7: 3, 1: 1, 3: 7, and 1: 9 was prepared. The same test method as described in the above-mentioned Test 6 “Drug Hazard Test 1 Using Pot”, except that a 0.5% by mass-containing liquid (diluted solution diluted 200-fold) for these five kinds of mixtures was used. did.

As a result of the test, “raw material (A): raw material (D)” = 9: 1, 7: 3, and 1: 1 were evaluated as “no phytotoxicity”. “Raw material (A): Raw material (D)” = 3: 7 and 1: 9 were evaluations of “very light”.
The test result of any mixture was “no phytotoxicity” or “extremely light”, and was a test result that could withstand on-site use.

  Next, when the raw material (B) was used instead of the raw material (A) and tested in the same manner, the same results as when the raw material (A) was used were obtained.

-Test 7-2-
Except for using each mixture prepared by mixing the raw material (A) and any one of the raw materials (E) to (H) at a mass-based content ratio of 1: 1, the same as in Test 7-1 above. Tested under conditions.

  As a result of the test, the mixture containing the raw material (E) was evaluated as “very light”, but each mixture containing the raw materials (F) to (H) was evaluated as “no phytotoxicity”.

  That is, the raw materials (D) to (H) all obtained good results. From the viewpoint of controlling phytotoxicity, it was considered more preferable to use a polyoxyalkylene alkyl ether having an alkyl group having 10 to 18 carbon atoms.

  From the above, it was considered that polyoxyalkylene alkyl ether can be used for spraying a small amount of water while suppressing phytotoxicity by using in combination with a specific POE-POP-POE block polymer and / or POP-POE-POP block polymer. . In addition, the content ratio based on mass may be within the range of “POE-POP-POE block polymer and / or POP-POE-POP block polymer: polyoxyalkylene alkyl ether” = 1: 9 to 9: 1. It was considered preferable.

  From the comprehensive results of the wettability test, it was considered more preferable to use a polyoxyalkylene alkyl ether having 10 to 16 carbon atoms in the alkyl group from the viewpoint of wettability and suppression of chemical damage.

[Test 8: Golf course test]
The following tests were conducted in a golf course bent grass nursery.

-Test area-
Test area 1: No treatment.
Test section 2: Mass-based content ratio “raw material (A): raw material (D)” = 1: 0.5% by weight of a liquid containing a mixture (diluted solution diluted 200 times) is sprayed.
Test group 3: A SB-99-containing solution containing 0.2% by mass (diluted solution obtained by diluting the stock solution 500 times) is sprayed.

-Test method-
Separate the nursery, it was prepared three compartments of 250m ^2. Prior to the test, the soil moisture content was measured in advance.
(1) For test group 2, the diluted solution was sprayed at 200 ml / m ² . For test group 3, the diluted solution was sprayed at 500 ml / m ² . In addition, the test group 1 did not perform the spraying process corresponding to these.
The first application date was May 17, and the first application date was the test start date.
(2) The dilution liquid described in (1) was sprayed once a month.
(3) The bent glass nursery of each test section was managed in accordance with the practice, and in addition to spraying of the diluent described in (1) above, water was appropriately sprayed with a sprinkler in anticipation of rainfall.

-Evaluation-
[Presence or absence of dry spots]
In test group 1, a dry spot was confirmed at 3 months after the start of the test. On the other hand, in Test Zone 2 and Test Zone 3, no dry spot occurred at the time of 3 months after the start of the test.

[Soil moisture content]
The soil moisture content of each test section was measured before the start of the test, in January after the start of the test, in February after the start of the test, and in 2.5 months after the start of the test. The soil moisture content was measured using a soil moisture meter SM-300 (manufactured by Delta-T). The measurement results are shown in Table 2 below.

[Table 2]

  As described above, in Test Zone 2 and Test Zone 3, no dry spot was generated, and the soil moisture content was also a good numerical value. The test group 2 was able to obtain a good result even when the spray amount of the diluent was less than half that of the test group 3. Therefore, it is thought that the 1: 1 mixture of the said raw material (A) and the raw material (D) is a composition suitable for small water quantity spraying.

  About the said raw material (A) and the said raw material (D) which are contained in the dilution liquid of the test area 2, favorable wettability was confirmed in the said test 3 and the said test 4. FIG. The 1: 1 mixture of the raw material (A) and the raw material (D) is evaluated as “very light” in the test 7.

  Therefore, it is considered that the raw materials and mixtures that have obtained good wettability evaluation in the above test 3 “screening test of raw material components” or the above test 4 “small water amount evaluation test of the mixture” are suitable for spraying a small amount of water on the soil. It is done.

  Furthermore, it is considered that the raw materials and mixtures that have obtained good results in the above-mentioned Test 6 or Test 7 “Pharm test using pots” are suitable for spraying a small amount of water on the soil where plants such as turf grow.

According to the present application, there is provided a soil treatment composition capable of improving the soil moisture content by spraying a small amount of water and exhibiting a good water repellent soil prevention effect / water repellent soil improvement effect.
Moreover, the soil treatment method which shows the generation | occurrence | production prevention effect of the favorable water-repellent soil / the improvement effect of water-repellent soil is provided.

Claims (5)

The soil treatment composition containing the following (a) component used for generation prevention of water-repellent soil and / or improvement of water-repellent soil.
(A) Polyoxyethylene-polyoxypropylene-polyoxyethylene glycol and polyoxypropylene-polyoxyethylene-poly having a number average molecular weight of 1500 to 3000 and a ratio of polyethylene oxide in the molecule exceeding 10% by mass One or more selected from oxypropylene glycol. Furthermore, the soil treatment composition of Claim 1 containing the following (b) component.
(B) One or more selected from polyoxyalkylene alkyl ethers. The soil treatment composition according to claim 1 or 2, wherein the cloud point of the 1% by mass water dilution is 20 ° C or higher. The soil according to claim 2 or 3, wherein a content ratio of the component (a) and the component (b) based on mass is (a) component: (b) component = 9: 1 to 1: 9. Treatment composition. The soil treatment composition according to any one of claims 1 to 4, which is sprayed at 300 ml / m ² or less.