JP2011132060A - Liquid fertilizer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid fertilizer containing 2,2'-iminodipropanoic acid and/or its salt. <P>SOLUTION: The liquid fertilizer includes 2,2'-iminodipropanoic acid and/or its salt as a stabilizer, further contains magnesium phosphite and has favorably a pH of 3.5 or below. The coordinate bond of calcium is favorably performed to 2,2'-iminodipropanoic acid and/or its salt. 2,2'-Iminodipropanoic acid and/or its salt, calcium and magnesium phosphite are dissolved in an aqueous medium and the liquid fertilizer is favorably clear. The content of 2,2'-iminodipropanoic acid and/or its salt is favorably 0.1 mass% or more and 30 mass% or less. A by-product produced in an alanine producing step is favorably used as 2,2'-iminodipropanoic acid and/or its salt. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a liquid fertilizer.

  Fertilizer is applied as a nutrient for growing a plant, and its components contain essential elements necessary for the growth of the plant. This essential element is classified into a large quantity essential element and a small quantity essential element according to the required amount. Among them, nitrogen (N), phosphorus (P), and potassium (K), which are classified as essential elements in large quantities, are three elements required in large quantities for plant growth. Nitrogen is a component that constitutes a protoplasmic protein that forms plant cells, and has physiological functions that promote cell division or proliferation, rhizome development, leaf growth, and nutrient absorption or assimilation. Phosphorus is a component of nucleic acids and enzymes in plants, and has a physiological effect of promoting root development, enhancing germination, and promoting flowering and fruiting. As for phosphorus, phosphorous acid has higher solubility in water than normal orthophosphoric acid, and the transition to phosphoric acid is more effectively performed in the plant body. Potassium is involved in the biosynthesis of proteins and carbohydrates in plants, intracellular and intercellular movement and accumulation, and has physiological functions that regulate root development and transpiration. On the other hand, as a trace essential element, metal elements, such as manganese (Mn), copper (Cu), zinc (Zn), or molybdenum (Mo), are mentioned, for example. However, even with the same metal element, magnesium (Mg) and calcium (Ca) are classified as essential elements in large quantities (for example, see Non-Patent Document 1).

  Magnesium is essential for all green plants as a component of plant chlorophyll, and is an important component that promotes plant metabolism and participates in protein and fat biosynthesis. Furthermore, since magnesium has an effect of promoting the absorption and transfer of phosphate in the plant body, using magnesium phosphite as a fertilizer is synergistic in effectively absorbing the phosphate in the plant body. The effect can be expected.

  On the other hand, calcium is a component sometimes called fertilizer four elements together with three elements of nitrogen, phosphoric acid and potassium, but unlike the above three elements, it adjusts the acidity of the soil rather than meeting the required amount. It plays a major role, and is sometimes called an intermediate element for the three elements. Calcium is an essential component for the growth of plant meristems, especially the root tips and shoots. When calcium is deficient, the growth point of the plant appears to be impaired, the entire plant atrophy, and the small size of the young shoots. Cause yellowing and yellowing. Further, calcium has been reported to exhibit disease resistance. Specifically, it has been reported that calcium exerts an effect on suppression of bacterial wilt of rice, rice blast, and soybean stem blight (see, for example, Non-Patent Document 2).

  Thus, although calcium is important for plant growth, most of it exists in the soil as poorly soluble calcium, so the plant cannot immediately absorb it, and the deficiency in the plant body is reduced. Easy to invite. In addition, plants cannot absorb a large amount of calcium instantaneously or in a short time, and calcium taken into the plant body is difficult to move through the plant body and moves from its storage location to a shortage location for reuse. Inability to do so is also a cause of deficiency. Therefore, it is necessary to continuously supply a certain amount of calcium to the plant.

  As a conventional fertilizer containing calcium, solid calcium phosphate has been generally used. However, calcium phosphate is hardly soluble in water, and it takes a very long time to dissolve in the soil. Moreover, as liquid fertilizer containing calcium, what mixed EDTA (ethylenediaminetetraacetic acid) and its salt as a chelating agent, and also what used EDTA calcium which chelated calcium directly are reported (for example, Patent Document 1). However, the chelating agent and the chelate salt are very expensive and difficult to use as a fertilizer component. Moreover, since EDTA has extremely poor biodegradability and cannot be decomposed in the soil by microorganisms, there are concerns about various effects caused by outflow to rivers and the like. Moreover, although the fertilizer which mix | blended calcium phosphite has been reported, since calcium phosphite is hardly soluble in water, when this is used as a liquid fertilizer, it becomes a suspension (for example, refer to Patent Document 2). Liquid fertilizer containing this calcium phosphite suspension may cause equipment malfunctions due to clogging of the sprayer nozzles, and if the suspension adheres to the crop, There is a defect that the value decreases.

JP 2007-145614 A JP 2006-176390 A

Eiichi Takahashi, “Searching for the individuality of silicate and lime plant crops”, Rural and Mountain Culture Association, April 1987 Written by Kazuhiko Watanabe, “Forefront of Nutritional Physiology of Crop Minerals and Crop, Human Health”, Rural and Mountain Fishing Village Cultural Association, December 2006

  The present invention has been made in view of these disadvantages, and by containing 2,2′-iminodipropanoic acid and / or a salt thereof, a liquid fertilizer capable of efficiently absorbing calcium in plants. It is for the purpose of provision. In addition, the present invention provides a liquid fertilizer that can be stably stored for a long period of time by containing 2,2′-iminodipropanoic acid and / or a salt thereof, which prevents formation and precipitation of insoluble solids. It is the purpose.

The invention made to solve the above problems is
A liquid fertilizer containing 2,2′-iminodipropanoic acid and / or a salt thereof as a stabilizer.

  The liquid fertilizer of the present invention can stabilize calcium as described later by containing 2,2'-iminodipropanoic acid and / or a salt thereof. By this action, the liquid fertilizer supplements calcium contained in the soil and the like, and can effectively absorb the calcium that tends to be deficient in the plant into the plant body.

  The liquid fertilizer may further contain magnesium phosphite. Thus, by containing 2,2′-iminodipropanoic acid and / or a salt thereof and magnesium phosphite at the same time, in addition to the calcium absorption promoting effect by the calcium supplementing action of 2,2′-iminodipropanoic acid. Thus, phosphorus can be efficiently supplied simultaneously in the state of phosphorous acid that is easily absorbed by plants. Furthermore, phosphorus can be effectively absorbed by the plant body due to the phosphorus absorption promoting action of magnesium.

  The pH of the liquid fertilizer is preferably 3.5 or less. Thus, precipitation and precipitation of magnesium phosphite can be effectively prevented by setting the pH of the liquid fertilizer to 3.5 or less.

  Calcium is preferably coordinated to the 2,2'-iminodipropanoic acid and / or salt thereof. In this way, 2,2'-iminodipropanoic acid and / or a salt thereof is already coordinated with calcium, so that only by spraying the liquid fertilizer, the plant can efficiently absorb calcium in a form that is easy to absorb. It becomes possible to supply. Moreover, it is effective that calcium is stabilized by 2,2'-iminodipropanoic acid and / or its salt being coordinated, and calcium is stabilized and the precipitate derived from calcium generate | occur | produces in a liquid fertilizer. Can be prevented.

  In the liquid fertilizer, 2,2'-iminodipropanoic acid and / or a salt thereof, calcium and magnesium phosphite may be dissolved in an aqueous medium. By dissolving these substances in an aqueous medium, it is possible to prevent clogging of devices such as the nozzles of the spreader, prevent contamination of the plant body after spraying, and prevent a decrease in commercial value. it can.

  The content of 2,2′-iminodipropanoic acid and / or a salt thereof in the liquid fertilizer is preferably 0.1% by mass or more and 30% by mass or less. Thus, by setting the content of 2,2′-iminodipropanoic acid and / or salt thereof in the liquid fertilizer within the above range, 2,2′-iminodi capable of coordinating and binding calcium sufficient for plants. Propanoic acid can be supplied. Moreover, by making content of 2,2'-iminodipropanoic acid and / or its salt into the said range, it can prevent effectively that the deposit derived from calcium, magnesium, etc. arises in liquid fertilizer. it can.

  As the 2,2'-iminodipropanoic acid and / or salt thereof, a by-product generated in the alanine production process may be used. By effectively using 2,2'-iminodipropanoic acid and / or a salt thereof contained in the by-product produced in the alanine production process, the intended liquid fertilizer can be produced at a lower cost.

  The liquid fertilizer is selected from the group consisting of iron (Fe), zinc (Zn), manganese (Mn), copper (Cu), selenium (Se), nickel (Ni), molybdenum (Mo) and boron (B). It is good to further contain 1 type or 2 types or more. Since these components are essential elements for plants, by containing the above components, the essential components can be efficiently given to the plant body in a balanced manner.

  As described above, the liquid fertilizer contains 2,2′-iminodipropanoic acid and / or a salt thereof, so that calcium can be stabilized in a water-soluble state that is easily absorbed by plants. Plants can efficiently absorb calcium. Therefore, the liquid fertilizer can effectively prevent plant calcium deficiency, and can prevent physiological disorders such as decay and necrosis of plant cells caused by calcium deficiency and various rot symptoms. As a result, the liquid fertilizer can improve the number of flowers and berries of the plant and the plant weight in the above-ground part, and a stable crop yield can be expected.

  In addition, the liquid fertilizer can efficiently absorb not only calcium but also phosphorus by containing magnesium phosphite at the same time. In addition, since the liquid fertilizer is an aqueous solution, it does not cause clogging of nozzles of a spreader, and further, does not cause contamination even when attached to a plant body, so that the quality of crops is not deteriorated. . As a result, the liquid fertilizer can be widely and suitably used for all plants such as crops and cut flowers.

It is a schematic diagram which shows the state in which 2,2'-iminodipropanoic acid has coordinated calcium. It is a photograph which shows the result of a fertilizer effect test (the 1). It is a photograph which shows the result of a fertilizer effect test (the 1). It is a photograph which shows the result of a fertilizer effect test (the 2). It is a photograph which shows the result of a fertilizer effect test (the 2).

Embodiments of the present invention will be described below with reference to the drawings as appropriate.
The liquid fertilizer contains 2,2′-iminodipropanoic acid and / or a salt thereof as a stabilizer.

(2,2'-iminodipropanoic acid)
2,2′-iminodipropanoic acid (2,2′-iminobispropanoic acid, IDPA) is a compound represented by the following formula, also called alanopine. The salt of 2,2′-iminodipropanoic acid is not particularly limited, and examples thereof include salts with alkali metals such as sodium and potassium, and salts with alkaline earth metals such as calcium and magnesium.

  2,2'-iminodipropanoic acid and / or a salt thereof has a function as a stabilizer because of its physical structure. As shown in FIG. 1, this is predicted to stabilize 2,2'-iminodipropanoic acid by coordinating an atom such as calcium in the molecule. As shown in FIG. 1, the fact that 2,2'-iminodipropanoic acid and calcium are bound in a tridentate configuration can also be confirmed by calculation using the molecular orbital method. When calcium is coordinated to the 2,2′-iminodipropanoic acid and / or its salt, the calcium is stabilized in a water-soluble state, and the plant can absorb calcium more effectively. .

  Moreover, precipitation of a hardly soluble precipitate in the liquid fertilizer can be effectively prevented by the stabilizing action of 2,2'-iminodipropanoic acid and / or a salt thereof. In general, liquid fertilizers are often stored for long periods in the natural environment such as outdoors or in warehouses, and calcium and magnesium contained in liquid fertilizers form salts when exposed to ultraviolet rays and high temperature conditions. However, these are likely to precipitate as hardly soluble precipitates. If this poorly soluble precipitate is contained in the liquid fertilizer, the sprayer nozzle will become clogged, causing malfunction of the equipment, or if the poorly soluble precipitate adheres to the surface of the plant body, The appearance looks dirty, causing inconveniences such as a reduction in commercial value. Since 2,2'-iminodipropanoic acid and / or its salt effectively prevents the generation of hardly soluble precipitates by the above-mentioned stabilizing action, these problems can be solved.

  The upper limit of the content of 2,2'-iminodipropanoic acid and / or a salt thereof is preferably 30% by mass, more preferably 25% by mass, and still more preferably 20% by mass with respect to the entire composition. On the other hand, the lower limit of the content of 2,2′-iminodipropanoic acid and / or a salt thereof is, for example, preferably 0.1% by weight, more preferably 1% by weight, and more preferably 5% by weight with respect to the entire composition. Is more preferable. Thus, by setting the content of 2,2′-iminodipropanoic acid and / or a salt thereof in the above range, a sufficient amount of calcium for plants can be obtained by 2,2′-iminodipropanoic acid and / or a salt thereof. While stabilizing, it can supply efficiently to a plant and generation | occurrence | production of a hardly soluble precipitate can be prevented effectively.

  The 2,2′-iminodipropanoic acid and / or salt thereof has been confirmed to be present in trace amounts in marine invertebrates such as bivalves, and is a by-product generated when the amino acid alanine is produced industrially. Alanine mother liquor is also abundant. The 2,2′-iminodipropanoic acid and / or salt thereof used in the liquid fertilizer can be used regardless of its origin, but is a byproduct produced in the alanine production process in that it can be obtained in large quantities at a low cost. It is preferable that it is 2,2'-iminodipropanoic acid derived from and / or its salt. The by-product alanine mother liquor produced in the alanine production process generally contains the above 2,2′-iminodipropanoic acid in an amount of about 10% by mass to 30% by mass, and 2,2′- In addition to iminodipropanoic acid, it contains about 5% by mass to about 10% by mass of alanine and about 2.5% by mass to about 4.2% by mass of nitrogen.

(calcium)
Calcium is an essential component that plays an important role in the structure and function of plant cell walls. When calcium is insufficient, defects such as the appearance of whitening in the leaves occur. By supplying calcium without excess or deficiency throughout the growing period of the plant, various physiological disorders of the plant can be prevented and a growth promoting effect can be expected. The calcium source in the liquid fertilizer is not particularly limited as long as it is a compound that generates calcium ions in an aqueous solution, and examples thereof include soluble lime such as organic acid calcium such as calcium nitrate, calcium chloride, or calcium citrate.

  The upper limit of the calcium content is preferably 6.0% by mass, more preferably 5.8% by mass, and even more preferably 5.5% by mass in terms of CaO with respect to the entire composition. On the other hand, as a minimum of the above-mentioned content of calcium, 0.1 mass% is preferred, 0.7 mass% is more preferred, and 1.0 mass% is still more preferred. Thus, by making content of calcium into the said range, sufficient quantity of calcium required for plant growth can be supplied, and the plant growth promotion effect by calcium can be expected.

  As described above, calcium is preferably coordinated to the 2,2'-iminodipropanoic acid. Since calcium is coordinated to 2,2'-iminodipropanoic acid, calcium is stably present in a water-soluble state, and plants can absorb calcium quickly. In addition, 2,2'-iminodipropanoic acid and / or a salt thereof stabilizes calcium, so that the insoluble calcium salt can be effectively prevented from being precipitated in the liquid fertilizer.

(Magnesium phosphite)
Magnesium phosphite is used to efficiently supply phosphorus, which is an essential component for plants, in a well-absorbed phosphorous acid state. Phosphorus is an essential component that contributes to promoting root development, maturation, increasing grain yield, and improving the quality of the harvest. Since phosphorus contained in magnesium phosphite takes the form of water-soluble phosphite ions in the liquid fertilizer, plants are easily taken up as a phosphorus source. Further, magnesium contained in magnesium phosphite has a function of promoting absorption of plant phosphorus. Therefore, by using magnesium phosphite, magnesium and phosphorus can be simultaneously supplied to the plant, and phosphorus can be absorbed more effectively into the plant body.

  As an upper limit of content of magnesium phosphite, 55 mass% is preferable with respect to the whole composition, 45 mass% is more preferable, and 35 mass% is further more preferable. On the other hand, as a minimum of content of magnesium phosphite, 0.1 mass% is preferred to the whole composition, 1 mass% is more preferred, and 5 mass% is still more preferred. Thus, by making content of magnesium phosphite into the said range, a plant can absorb phosphorus more effectively by the phosphorus absorption promotion effect of magnesium.

(Rin)
The phosphorus source used in the liquid fertilizer is preferably a water-soluble phosphite compound that releases phosphite ions in the liquid fertilizer. As such a water-soluble phosphite compound, the above-described magnesium phosphite may be used, or other compounds may be used. Examples of other compounds include, but are not limited to, ammonium phosphite, potassium phosphite, or sodium phosphite. These compounds may be used individually by 1 type, and may use 2 or more types together.

(magnesium)
The magnesium source used for the liquid fertilizer is preferably a water-soluble compound that releases magnesium ions in the liquid fertilizer. As such a water-soluble compound, the above-described magnesium phosphite may be used, or other compounds may be used. As other compounds, for example, water-soluble magnesium salts are preferable, and specific examples include magnesium chloride, magnesium sulfate, magnesium nitrate, and the like. These compounds may be used individually by 1 type, and may use 2 or more types together.

(Metal element)
In addition to the above components, the liquid fertilizer includes, for example, iron (Fe), zinc (Zn), manganese (Mn), copper (Cu), selenium (Se), nickel (Ni), molybdenum (Mo), iodine (I ), Cobalt (Co), vanadium (V), fluorine (F), silicon (Si), boron (B), tin (Sn), or the like. Among these components, iron (Fe), zinc (Zn), manganese (Mn), copper (Cu), selenium (Se), nickel (Ni), molybdenum (Mo) or boron (B) is preferable. What is necessary is just to add these components to the said liquid fertilizer as water-soluble compounds, such as copper sulfate, zinc sulfate, or ammonium molybdate, for example.

  Among the above components, boron is an important component for plants that has an effect of promoting flower bud differentiation, pollen germination and fruit cell division. Boron also has the effect of enhancing sugar translocation, maintaining growth at the growth point, enhancing calcium absorption, and strengthening the cell wall. Legumes, cruciform plants, fruit trees with a large number of flowers, etc. have a large amount of demand, and since they exist in an inorganic state in the soil, they tend to be insufficient in outdoor cultivation.

As a boron source used for the liquid fertilizer, a water-soluble boron compound is preferable, and examples thereof include boric acid or a salt thereof (for example, sodium borate). The upper limit of the content of the water-soluble boron _compound, based on the entire composition as a B 2 _{O 3,} preferably 0.5% by mass, more preferably 0.4% by mass, more preferably 0.3% by mass. Moreover, as a minimum of the said content of a water-soluble boron compound, 0.001 mass% is preferable, 0.005 mass% is more preferable, 0.01 mass% is further more preferable. Thus, the sufficient quantity of boron which a plant requires can be supplied by making content of a water-soluble boron compound into the said range.

  The upper limit of the content of the metal component other than boron varies depending on the type, but is preferably 3% by mass, more preferably 2% by mass, and still more preferably 1% by mass with respect to the entire composition. Moreover, as a minimum of content of the said metal component other than boron, 0.001 mass% is preferable, 0.005 mass% is more preferable, 0.008 mass% is further more preferable. Thus, by setting the content of the metal component other than boron within the above range, a sufficient amount of the component necessary for plant growth can be effectively supplied. Moreover, the above-mentioned metal components other than boron may be used alone or in combination of two or more.

(nitrogen)
The liquid fertilizer may further contain nitrogen in addition to the above components. Nitrogen is a component necessary for protein synthesis, cell division, proliferation, flower bud formation, root development, nutrient absorption, or promotion of anabolism. The nitrogen source used for the liquid fertilizer is not particularly limited, but is preferably in the form of urea nitrogen, ammonia nitrogen, nitrate nitrogen or the like, and among them, ammonia nitrogen or nitrate nitrogen is more preferable. Examples of such nitrogen sources include nitric acid, ammonium nitrate, calcium nitrate, potassium nitrate, sodium nitrate, ammonium sulfate (ammonium nitrate + ammonium sulfate), ammonium lime (ammonium nitrate + calcium carbonate), ammonium sulfate, ammonium chloride, monobasic ammonium phosphate, Examples thereof include dibasic ammonium phosphate, ammonium hydroxide, ammonium borate, ammophos (ammonium sulfate + dibasic ammonium phosphate), urea, calurea (urea + calcium nitrate), various amino acids, beans and fish broth. The upper limit of the nitrogen content in the liquid fertilizer is preferably 12% by mass, more preferably 10% by mass, and still more preferably 8% by mass with respect to the entire composition. Moreover, as a minimum of content of nitrogen, 1 mass% is preferable, 3 mass% is more preferable, and 5 mass% is further more preferable.

(potassium)
The liquid fertilizer may further contain potassium in addition to the above components. Potassium is an important component for plants that has physiological effects such as synthesis of carbohydrates and nitrogen compounds, promotion of assimilation, promotion of root development, water supply, increased resistance to cold and pest damage, and promotion of flowering and fruiting. is there. As a potassium source used for the liquid fertilizer, a water-soluble potassium compound that releases potassium ions in the liquid fertilizer is preferable. Such water-soluble potassium compounds include, for example, primary potassium phosphate, secondary potassium phosphate, tertiary potassium phosphate, potassium pyrophosphate, potassium tripolyphosphate, potassium nitrate, potassium chloride, potassium carbonate, potassium sulfate, water Examples thereof include potassium oxide and potassium acetate. These compounds may be used individually by 1 type, and may use 2 or more types together. The upper limit of the content of potassium above, the total composition as K 2 _O, preferably 15 wt%, more preferably 12 wt%, more preferably 10% by mass. Moreover, as a minimum of content of potassium, 1 mass% is preferable, 3 mass% is more preferable, and 5 mass% is further more preferable.

(PH)
The pH of the liquid fertilizer is preferably 3.5 or less, and more preferably 3 or less. Any pH adjusting agent can be used as long as it is a commonly used pH adjusting agent, but an aqueous phosphoric acid solution is particularly preferable. Thus, by setting the upper limit of pH, it can prevent that magnesium phosphite etc. precipitate as an insoluble precipitate, and can keep the said liquid fertilizer clear.

(Optional component)
In addition to the above components, the liquid fertilizer can further contain other components as long as the object of the present invention is not impaired. Examples of such other components include vitamins (for example, vitamin B1, vitamin B6, nicotinic acid amide, choline salts), anti-corrosion agents (for example, benzoic acid, sorbic acid, propionic acid, etc.), surfactants, and the like. (For example, nonionic surfactants, anionic surfactants, carboxylic acid surfactants, sulfonic acid surfactants, sulfate ester surfactants, phosphate ester surfactants, amphoteric surfactants, etc.) Or a coloring agent (for example, blue No. 1 etc.) etc. are mentioned.

(Manufacturing method of liquid fertilizer)
Examples of the method for producing the liquid fertilizer include dissolving each component such as 2,2′-iminodipropanoic acid and / or a salt thereof, magnesium phosphite, etc. in water, and filtering or adjusting pH as desired. It is done. Examples of water include, but are not limited to, tap water, purified water, ion exchange water, and distilled water. The dissolution may be performed by a known means such as a stirrer at room temperature, and may be heated to promote dissolution as desired. For the filtration and pH adjustment, known means may be appropriately employed.

(How to use liquid fertilizer)
As a method for using the liquid fertilizer, for example, the liquid fertilizer may be diluted to about 100 to 5000 times volume with water and then supplied to a plant body or the like. As a method for supplying to the plant, for example, a method in which the diluted liquid fertilizer is directly sprayed on leaf surfaces, stems, fruits, etc., a method of injecting into the soil, a hydroponic culture or rock wool and the like in contact with the root For example, a method of diluting and supplying to the hydroponic liquid or supply water. That is, the method of spraying on the ground parts, such as a leaf surface of a plant, irrigating to the soil of soil cultivation, adding to the hydroponics of hydroponics, and immersing a seedling in dilution liquid are mentioned. Especially, the method of adding to the hydroponic liquid of the foliage spraying to the above-ground part of plants, such as a foliage, and hydroponics is preferable. Dilution water is not specifically limited, What is necessary is just to use the water similar to the water used at the time of manufacture of the said liquid fertilizer, and the water normally used at the time of cultivation of a farmer.

  The time for applying the liquid fertilizer may be any time from planting to harvesting. Since the number of times of application varies depending on the type of plant body and the degree of growth, it cannot be said unconditionally. However, it is preferable to increase the number of times as much as possible because the effect appears stably. The application amount may be appropriately adjusted according to the growth stage of the plant body. For example, in the case of spraying treatment in the seedling stage, it is only necessary to spray an amount that allows water droplets to adhere to the site to be sprayed.

  When the liquid fertilizer is applied to a plant body, favorable results in terms of plant growth such as increase in yield, promotion of leaf and root growth, promotion of flower bud formation, increase in the number of flowers, and promotion of flowering can be obtained. As the plant to which the liquid fertilizer is applied, it can be applied to any plant, for example, cucumber, pumpkin, watermelon, melon, tomato, eggplant, pepper, strawberry, okra, sweet bean, broad bean, pea, edamame, shiitake, chili pepper, Fruit and vegetables such as peanuts, corn; Chinese cabbage, komatsuna, chinensai, cabbage, cauliflower, broccoli, mecabbage, leek, garlic, radish, leek, asparagus, lettuce, salad vegetable, celery, spinach, sengoku, parsley, honeybee, seri, udo , Myoga, buffalo, perilla, shungiku, silkworm radish, watercress, etc .; radish, turnip, burdock, carrot, potato, taro, sweet potato, yam, ginger, lotus root, radish, onion, garlic Root vegetables; citrus such as mandarin, apples, pears, grapes, peaches, persimmons, chestnuts, plum, cherry, loquat, pineapple, fruit trees such as banana and the like. In addition, it can also be used for rice, wheat, and flowering plants.

  EXAMPLES Hereinafter, although this invention is explained in full detail based on an Example, this invention is not interpreted limitedly based on description of this Example. In the following examples, “%” indicates “% by mass”.

[Test Example 1] Stability test (1)
The components listed in Table 1 below and the blending amounts thereof were mixed to produce each liquid fertilizer (Example Product 1, Comparative Example Product 1). Further, Example Product 1 and Comparative Product 1 were adjusted to pH 2.8 with an aqueous phosphoric acid solution, and each liquid fertilizer after adjustment was stored at room temperature for 2 weeks. Was observed.

The “alanine mother liquor” in Table 1 above is a byproduct obtained during the production of alanine. The properties and composition of the “alanine mother liquor” are shown below. The following “alanine mother liquor” in the examples is also the same.
<Properties>
Appearance ... Yellow liquid Odor ... Sweet scent Specific gravity ... 1.12-1.14 (20 ° C)
pH ... 5-6
<Composition>
Moisture ... 65-75%
Alanine 5-10%
Impurities ... 8-10%
Na ... 10,000-30,000 ppm
N minutes: 2.5-4.2%
(Alanine 10%, IDPA 30%, N min 4.2%)

(result)
As a result, in the comparative product 1 that did not contain 2,2′-iminodipropanoic acid, a white precipitate was formed in about 1 hour after the preparation. On the other hand, in Example Product 1 containing 2,2′-iminodipropanoic acid, no insoluble precipitate was observed even after 2 weeks. This indicates that calcium is stabilized in the aqueous solution by coordination of calcium to 2,2′-iminodipropanoic acid.

[Test Example 2] Stability test (2)
Components shown in Table 2 below and the blending amounts thereof were stirred and mixed at room temperature to produce 100 g of a clear yellow-brown liquid fertilizer (Example Product 2). Various components contained in Example Product 2 are shown in Table 3. The product of Example 2 was stored at a constant temperature of 45 ° C. for 2 weeks, and the presence or absence of insoluble precipitate was observed.

  In Table 3 above, “TN” means “total nitrogen”, “WP” means “water-soluble phosphoric acid”, “CaO” means “calcium oxide”, and “MgO” means “magnesium oxide”. The same applies to the following.

(result)
As a result, no precipitation of insoluble precipitates was observed even after 2 weeks, and no change in properties was observed.

[Test Example 3] Stability test (Part 3)
The components listed in Table 4 below and the blending amounts thereof were stirred and mixed at room temperature to produce 100 g of a tan clear liquid fertilizer (Example Product 3). Various components contained in Example Product 3 are shown in Table 5. The example product 3 was stored at a constant temperature of 45 ° C. for 2 weeks, and the presence or absence of insoluble precipitate was observed.

(result)
As a result, no precipitation of insoluble precipitates was observed even after 2 weeks, and no change in properties was observed.

[Test Example 4] Stability test (4)
The components listed in Table 6 below and the blending amounts thereof were stirred and mixed at room temperature to produce 100 g of a clear yellow-brown liquid fertilizer (Example Product 4). Various components contained in Example Product 4 are shown in Table 7. Example product 4 was stored at a constant temperature of 45 ° C. for 2 weeks, and the presence or absence of insoluble precipitate was observed.

In Table 7 above, “Zn” means “zinc”, “Mn” means “manganese”, and “B ₂ O ₃ ” means “boron oxide”.

(result)
As a result, no precipitation of insoluble precipitates was observed even after 2 weeks, and no change in properties was observed.

[Test Example 5] Stability test (5)
(1) When 1 mL of a 5% by mass sodium carbonate aqueous solution was added to 20 mL of a 10% by mass calcium nitrate aqueous solution, calcium carbonate was instantaneously generated and the solution became cloudy.
(2) Even if 1 mL of 5% by weight sodium carbonate aqueous solution is added to 20 mL of calcium nitrate aqueous solution (10% by weight) containing 10% by weight of 2,2′-iminodipropanoic acid, changes in the properties of the solution are observed. I couldn't.
(3) Further, when 20 mL of 10% by mass of 2,2′-iminodipropanoic acid aqueous solution was added to the cloudy aqueous solution obtained in the above (2), it returned to the original transparent aqueous solution even when the cloudiness disappeared. .

(result)
From the results of the above (1) to (3), 2,2′-iminodipropanoic acid coordinates calcium and stabilizes calcium in an aqueous solution, thereby preventing the formation of insoluble calcium carbonate. I understand that.

[Test Example 6] Fertilizer effect test (1)
(Test method)
Hydroponic cultivation of corn seedlings (4 varieties: “Gold Rush”, Sakata Seed Co., Ltd.) for 42 days in a greenhouse (no temperature and humidity control, illuminance is natural light) The growth promoting effect of the liquid fertilizer was verified. In addition, the “calcium-deficient medium” of the hydroponic liquid in Table 8 below means a hydroponic liquid prepared according to the standard prescription of the horticultural laboratory, which lacks the calcium component, NO ₃ ⁻ : 16 me / l, NH ₄ ⁺ : 1.33 me / l, P: 4 me / l, K: 8 me / l, Mg: 4 me / l. “Me / l” means “milli-equal per liter (milligram equivalent / l)”.

  In each test section, 10 corn seedlings were used. As the liquid fertilizer, a diluted solution obtained by diluting each liquid shown in Table 8 500 times with water was sprayed once every three days with a spreader to such an extent that water droplets adhered to the leaves and stems.

(result)
The results are shown in Table 9, FIG. 2 and FIG. In addition, the numerical value of Table 9 is an average value of the numerical value obtained in each test section.

  From the results of Table 9, FIG. 2 and FIG. 3, it was proved that the liquid fertilizer of the present invention has an effect of promoting the growth of plants. Moreover, although the growth promotion effect was confirmed also in the test group (test group 2) which gave the liquid fertilizer containing 2,2'- imino dipropanoic acid and / or its salt, calcium nitrate and magnesium phosphite were further added. It was found that the test group (test group 3) to which the liquid fertilizer contained contained exceeded the numerical values of the test group 2 in terms of the length and weight of the foliage, and the growth promotion effect was higher. This is because 2,2′-iminodipropanoic acid and / or a salt thereof in the liquid fertilizer supplements calcium in the liquid fertilizer in advance, so that the plant can easily take up calcium and magnesium phosphite This is probably because phosphorus was efficiently absorbed by plants.

[Test Example 7] Fertilizer effect test (2)
(Test method)
In the greenhouse (temperature 25 ° C, humidity is not controlled, the illuminance is natural light), cultivated young radish seedlings (variety: “Komet”, manufactured by Takii Seed Co., Ltd.) for 30 days The calcium absorption promotion effect and the growth promotion effect of the liquid fertilizer of the present application were compared and verified. Each composition of the sprayed liquid fertilizer is shown in Table 10 below. In Table 10 below, the “calcium-deficient medium” of the hydroponics is the same as the “calcium-deficient medium” used in the fertilizer effect test (Part 1). “Anone” in Table 10 below is a surfactant, and “Nissan Anon LG” manufactured by NOF Corporation was used.

  In each of the test sections, 10 radish seedlings were used. The liquid fertilizer was sprayed with a diluting solution obtained by diluting the composition shown in Table 10 200 times with water at intervals of once every 3 days with a spreader to such an extent that water droplets adhered to the leaves and stems.

(result)
The results are shown in Table 11, FIG. 4 and FIG. In addition, the numerical value of Table 11 is an average value of the numerical value obtained in each test section.

  From the results of Table 11, FIG. 4 and FIG. 5, it was proved that the liquid fertilizer of the present invention has an effect of promoting calcium absorption and plant growth (test sections AD-1, AD-4). . On the other hand, in the test group (AD-2) to which EDTA and calcium were given and the test group (AD-3) to which only calcium was given, the growth promoting effect was hardly seen, and the fresh weight and calcium absorption amount were not treated. There was not much difference from the ward.

As described above, since the liquid fertilizer contains 2,2′-iminodipropanoic acid and / or a salt thereof as a stabilizer, calcium can be absorbed into the plant very efficiently. Moreover, since it is cheap and can be manufactured easily, it is very useful as a liquid fertilizer for cultivation of crops and the like.

Claims (8)

  Liquid fertilizer containing 2,2'-iminodipropanoic acid and / or a salt thereof as a stabilizer.   The liquid fertilizer according to claim 1, further comprising magnesium phosphite.   The liquid fertilizer according to claim 1 or 2, having a pH of 3.5 or less.   The liquid fertilizer according to claim 1, 2 or 3, wherein calcium is coordinated to the 2,2'-iminodipropanoic acid and / or a salt thereof.   The liquid fertilizer according to any one of claims 1 to 4, wherein the 2,2'-iminodipropanoic acid and / or a salt thereof, calcium and magnesium phosphite are dissolved in an aqueous medium.   The liquid fertilizer according to any one of claims 1 to 5, wherein a content of the 2,2'-iminodipropanoic acid and / or a salt thereof is 0.1 mass% or more and 30 mass% or less.   The liquid fertilizer according to any one of claims 1 to 6, wherein a byproduct produced in the alanine production process is used as the 2,2'-iminodipropanoic acid and / or a salt thereof. One or two selected from the group consisting of iron (Fe), zinc (Zn), manganese (Mn), copper (Cu), selenium (Se), nickel (Ni), molybdenum (Mo) and boron (B) The liquid fertilizer according to any one of claims 1 to 7, further comprising a seed or more.