JP5205588B2 - Culture soil improvement material and culture soil containing artificial zeolite - Google Patents

Description

  The present invention relates to a culture soil improvement material and culture soil containing artificial zeolite, and more specifically, a culture soil improvement material containing artificial zeolite and nutrient components necessary for plant growth, and the culture soil improvement material. The present invention relates to cultured soil containing artificial zeolite.

  Traditionally, horticulture has been carried out using land such as a garden of a house, but in recent years, houses without land such as high-rise houses have increased. Residents of high-rise housing do not have land, so buy culture soil, use containers (containers) such as pots and planters, or purchase flowers and houseplants planted in pots for gardening There are many cases.

  For residents of high-rise housing, it is wasteful to throw away the used culture soil every time it is used, and it is difficult to discard the culture soil, so it is desirable to reuse the culture soil once used. However, the culture soil once used often does not grow well even if it is reused as it is. Culture soil that has changed in this way is called culture soil with reduced geological strength.

  The reason why the soil strength of the culture soil is reduced is that in containers such as pots and planters, in order to cultivate a large number of plants efficiently using a small amount of culture soil, compared to plant cultivation using the ground such as a garden. Depletion of soil organic matter and minerals, soil grains becoming finer, etc., deteriorating breathability, water permeability (drainage), water retention, fertilizer retention, etc., soil pests Can often be said to have been bred.

  Artificial zeolite has been reported as a soil improvement material for acidic soil (see, for example, Patent Document 1). Artificial zeolite mixed culture soil has been reported as the culture soil (see, for example, Patent Document 2). As a soil improvement material containing artificial zeolite, a cultivation material for preventing root rot has been reported (for example, see Patent Document 3).

Japanese Patent Laid-Open No. 2007-2007 JP 2004-131327 A JP-A-8-9771

  For example, conventional methods for restoring the soil strength of cultured soil with reduced ground strength include removing soil from containers such as pots and planters that have been used, removing the roots of plants, disinfecting them with sunlight, There is a method of mixing culture soil improving material. However, the conventional method is complicated when enjoying gardening easily. Therefore, it has been desired to develop a culture soil improving material that can recover the soil strength of the culture soil simply by mixing it with the soil with reduced ground strength.

Patent Documents 1 and 3 describe soil improvement materials using artificial zeolite. Since artificial zeolite prevents root rot, it is effective for reusing culture soil. However, only by adding artificial zeolite to the culture soil, organic matter and minerals remain reduced, and these must be added, which is complicated. Patent Document 2 relates to horticultural culture soil containing artificial zeolite.
An object of the present invention is to provide a culture soil improving material containing artificial zeolite that recovers the ground strength of the cultured soil simply by mixing with the cultured soil with reduced ground strength, and a culture soil containing the cultured soil improving material. is there.

The culture soil improving material containing the artificial zeolite of the present invention for solving this object is characterized by containing an artificial zeolite containing 3 to 10% by weight of activated carbon-like unburned carbon and an organic fertilizer.
The present invention further includes artificial zeolite and a water-soluble ferrous ion (Fe ²⁻ ) salt and / or ferric ion (Fe ³⁻ ) salt .

  Furthermore, the culture soil of the present invention comprises the above-mentioned soil improving material and one or more soils selected from pumice, peat moss, coco pate, compost, perlite, akadama soil, humus, vermiculite, bark, bark compost, coconut, and charcoal. , Are mixed.

According to the present invention, and artificial zeolite produced as containing unburned carbon in activated carbon like, and organic fertilizer, and water-soluble minerals, a culture soil improvement agent comprising artificial zeolite consisting of, with decreased fertility culture By mixing with soil, the soil strength of the cultured soil can be improved.

  Fertilizer burning due to over-fertilization is eliminated by the adsorption capacity of artificial zeolite, the retention of fertilizer and moisture is improved, and harmful substances such as organic acids in the soil generated from plants during cultivation are removed, and cultivation with organic fertilizer Organic matter in the soil is replenished, soil bacteria are activated, and iron is added to improve mineral deficiency and balance in the cultured soil. As a result, the ground strength of the culture soil with reduced ground strength can be improved.

Embodiments of the present invention will be described below.
Potting modifying material described in the present invention, the artificial zeolite containing unburned carbon in activated carbon like, and organic fertilizer, a water-soluble mineral consists, by mixing the reduced potting soil fertility, the It is an improved material that can improve the soil strength of cultured soil.

The artificial zeolite according to the present invention has a strong adsorptive power for fertilizer components, and when added to soil, the fertilizer can be prevented from being washed away, and the fertilizer can be gradually supplied. Moreover, since artificial zeolite contains a large amount of soluble silicon and calcium, it is effective for supplementing minerals of culture soil. Furthermore, since artificial zeolite can absorb soil pollutants such as agricultural chemicals and heavy metals, the soil can be purified.
When cultivating plants, if the supplied fertilizer flows without being absorbed by the plant or soil, it will flow from the groundwater to the river and the sea, causing environmental pollution such as the occurrence of blue sea bream and red tide. Environmental pollution caused by fertilizer runoff can be prevented.

  The artificial zeolite is an industrial waste containing a silicic acid component and / or an aluminum component, a natural waste containing silicic acid and aluminum as an amorphous aluminum silicate salt, an incineration ash of industrial waste, or an incineration of combustible waste. It is a substance having a cation exchange capacity obtained by mixing a silicate-enriched material or an aluminum-enriched material with ash or the like and heating or applying a pressure reaction under alkaline conditions.

The crystal form of the artificial zeolite produced varies depending on the silica ratio of the raw material, that is, the molar ratio of SiO ₂ and Al ₂ O ₃ . Mainly produced are hydroxy sodalite, philipsite, faujasite and the like. Other products may contain a small amount of zeolite A and the like. As non-zeolite components, unburned carbon-derived activated carbon analogs, iron, other impurities, and intermediate products up to zeolite are also present. In practicing the present invention, it is preferable to use an artificial zeolite mainly composed of philipsite having excellent adsorption ability.

The artificial zeolite according to the present invention is a cation-substituted artificial zeolite. Preferable examples include artificial zeolite substituted with one or more of Ca ²⁺ , ion Mg ²⁺ ion, Fe ²⁺ ion, and Fe ³⁺ ion. Furthermore, as a more preferable specific example, an artificial zeolite substituted with Ca ²⁺ ions produced using coal-fired soot of a thermal power plant as a raw material can be exemplified.

The water-soluble mineral described in the present invention is a mineral component necessary for plant growth, and specifically iron, calcium, magnesium and silicon. These minerals are important next to nitrogen, phosphoric acid, and potash, which are said to be the three major fertilizers of plants. Sulfur is also an important element for plants, but if sulfur is added too much, it causes acidification of the culture soil, so it is not added in the present invention.
When these minerals are supplied to plants, they must be supplied in a soluble state in water.

When the iron is deficient, chlorosis, which leaves the leaves and leaves yellow, is generated at the new site of the plant, and the growth of the plant stops. It is said that iron deficiency does not occur when plants are cultivated in the open space, but when containers such as planters and pots are used repeatedly, soil is often deficient.
When a water-soluble iron salt is added, either a ferrous ion (Fe ²⁻ ) salt or a ferric ion (Fe ³⁻ ) salt may be used. Ferrous ion (Fe ²⁻ ) is less acidified in the soil than ferric ion (Fe ³⁻ ) salt, or ferric ion (Fe ³⁻ ) precipitates as insoluble ferric oxide. because cheap, ferrous ion ^{(Fe 2-)} salts are more preferable. Usually, ferrous ions (Fe ²⁻ ) are oxidized by oxygen in the air to be converted to ferric ions (Fe ³⁻ ), but in the present invention, artificial zeolite is converted to ferrous ions ( Fe ²⁻ ) is protected and ferrous ions (Fe ²⁻ ) are stabilized.

The amount of the water-soluble iron salt added to the present invention is 0.01 to 10%, preferably 0.1 to 5% by weight% as iron content relative to the artificial zeolite.
The iron can also be added by using artificial zeolite substituted with Fe ions instead of artificial zeolite substituted with Ca ²⁺ ions.

The calcium, because it contains artificial zeolite was replaced with Ca ²⁺ ions, by adding artificial zeolite was replaced with Ca ²⁺ ions in the culture soil, without any additional calcium separately, calcium culture soil Can be replenished. When using artificial zeolite other than substituted artificial zeolite with Ca ²⁺ ions it is desirable to add Ca ²⁺ ions.

  Since the silicon is contained in the artificial zeolite, in the present invention, by adding the artificial zeolite to the culture soil, the silicon in the culture soil can be replenished without additional silicon. it can.

Since the magnesium is contained in a small amount in the artificial zeolite, magnesium is not particularly added in the present invention. By adding the artificial zeolite substituted with Mg ²⁺ ions, magnesium in the culture soil can be supplemented without additional magnesium. When a magnesium deficiency such as the fall of a lower leaf appears in a plant being cultivated, it is desirable to add magnesium separately.
Thus, by mixing artificial zeolite and iron, minerals can be replenished to the culture soil in a well-balanced manner.

The artificial zeolite according to the present invention is also an artificial zeolite containing activated carbon-like unburned carbon. Although artificial zeolite originally contains activated carbon-like substances derived from unburned carbon, artificial zeolite containing activated carbon-like unburned carbon described in the present invention limits the supply of air when producing zeolite, Combustion is prevented, and the activated carbon-like substance content derived from unburned carbon is increased.
Since the activated carbon analog adsorbs contaminants in the soil, the activated carbon analog in the artificial zeolite can increase the potency of the cultured soil amendment.

The amount of the activated carbon-like unburned carbon is 1 to 20%, more preferably 2 to 15%, and most preferably 3 to 10% in weight% with respect to the artificial zeolite containing activated carbon-like unburned carbon. is there.
The amount of the artificial zeolite used in the present invention or the artificial zeolite containing activated carbon-like unburned carbon is 20 to 95%, more preferably 40 to 95% of the culture soil improving material containing the artificial zeolite. 90%, most preferably 60-80%.

The organic fertilizer described in the present invention is a fertilizer using organic matter as a raw material, and raw fertilizers such as oil lees, fish lees, persimmons, compost, horse dung, cow dung, chicken dung, human manure, bone meal, meat and bone meal, etc., and fermentation treatment of these Fertilizer.
As a preferable organic fertilizer, a granular organic fertilizer and an amino acid fertilizer can be illustrated.
The granular organic fertilizer is obtained by fermenting cow dung or chicken dung and granulating it. Granular fermented chicken manure is obtained by pulverizing fermented chicken manure with a hammer mill, granulating with a pelleta, and sieving. Granulated beef manure compost is made by adding additives such as soil conditioner to beef manure, granulated with a pellet, and sieved.

The amino acid fertilizer is also referred to as “bokashi fertilizer” and is fermented by adding water to organic fertilizer. Organic fertilizers used as raw materials are diverse, such as oil residue, rice bran, chicken dung, fish residue and bone meal. Inorganic fertilizer may be added. By fermenting organic fertilizer, nutrients in the fertilizer are decomposed and absorbed and used by plants, improving the color of leaves. In addition, the amino acid fertilizer serves as a nutrient source for microorganisms, the number of fungi in the soil increases, and the soil is aggregated.
The amount of the organic fertilizer used in the present invention is 5 to 98%, more preferably 10 to 60%, and most preferably 20 to 40% of the culture soil improving material containing artificial zeolite in weight%. %.

The culture soil containing the artificial zeolite described in the present invention is a culture soil obtained by mixing the culture soil improving material containing the artificial zeolite with the soil.
The culture soil is a mixing soil or a single-use soil in which a single-use soil is mixed so that it can be used as it is in accordance with a plant to be cultivated in advance.
Examples of the soil for single use include pumice, peat moss, coco pate, compost, pearlite, red jade soil, humus, vermiculite, bark, bark compost, eggplant, and charcoal.

The above-mentioned pumice is a rock formed by releasing a gas contained when lava is rapidly cooled from a volcano to form a porous sponge, and has excellent air permeability.
The peat moss is a peat moss deposited from wetlands and mud carbonized. It has properties similar to humus, is homogeneous and almost aseptic, and is suitable for indoor cultivation. However, peat moss is different from humus in that it is strongly acidic, contains almost no trace elements, and has a weak ability to activate microorganisms.

  The above-mentioned coco pate is a product obtained by depositing and fermenting the remainder of the coconut fruit hard fiber, which makes mats and ropes, for 3 to 5 years. It is a soil conditioner that replaces peat moss. It is similar to peat moss at first glance, but is widely used as a soil conditioner that has properties that surpass peat moss.

  The above-mentioned compost refers to a fertilizer made by stacking and decaying food residue, straw, garbage, fallen leaves, excrement, etc., and examples thereof include beef manure fermented and dried from cow dung. Compost contains some fertilizer, but not enough to grow plants. In addition, the soil for improvement works the same as humus.

  The pearlite is a porous and light artificial gravel obtained by finely crushing obsidian and pearlite and treating them at high temperature and pressure. It has excellent breathability and drainage, and is effective in improving the physical properties of soils with poor breathability. Moreover, although the said pearlite can be utilized for the weight reduction of pot soil, since water retention and fertilizer retention are not good, when improving water retention and fertilizer retention, it is necessary to make particle size fine.

In the Kanto Loam Formation, the red crust is present in the lower layer of the black soil and the upper layer of the Kanuma soil, and does not contain organic matter and is a weakly acidic viscous volcanic ash soil that is sifted into large, medium, and small particle sizes. is there. Although red soil itself has a small particle size and poor air permeability, granular red jade soil is an almost aseptic weakly acidic soil that is rich in air permeability, water retention and fertilizer, and is excellent as a soil for containers.
The humus is a kind of compost obtained by corroding and fermenting fallen leaves. Used in combination with other soils, activates microorganisms in the soil and increases the air permeability of the soil.

  The vermiculite is a product obtained by treating a meteorite with a high temperature and expanding it, and is aseptic and homogeneous. The meteorite has a shape in which thin plates are gathered in layers, can store moisture and nutrients between the layers, and has air permeability.

  The bark is a bark chip (chip of bark of conifers) that has been crushed and cut into pieces, has excellent air permeability, and is more fertile than pumice. As improved soil, it has the same function as Isogara.

The bark compost is a soil improver made by fermenting a bark portion of a tree. When mixed with soil when planting trees or planting agricultural products, fertilizer, water retention, and air permeability in the soil are increased, which is good for growing trees and agricultural products. It also leads to an improvement in the balance of soil microorganisms and has the effect of suppressing the occurrence of continuous cropping disorders and the like.
The above-mentioned coconut shells are obtained by pulverizing and chopping the coconut shells, and are excellent in air permeability and fertilizer and water retention properties than bark.

  The above-mentioned charcoal is obtained by smoldering and carbonizing rice husks, has excellent ventilation, and has a rooting prevention effect. Almost sterile, weakly acidic soil with excellent air permeability, water retention and fertilizer retention, and excellent as a soil for containers.

The mixing ratio of the soil for single use in culture soil is arbitrary.
The amount of the culture soil improving material containing artificial zeolite used for the culture soil containing the artificial zeolite of the present invention is 1 to 20% of the culture soil containing the artificial zeolite in weight%, and more preferably 1 to 10%. %.

(Formulation example)
An artificial zeolite substituted with Ca ²⁺ ions or an artificial zeolite containing activated carbon-like unburned carbon is mixed with organic fertilizer or / and ferrous sulfate to produce a culture soil improving material containing artificial zeolite of A to F, It is shown in Table 1.

A dry soil sludge discharged from a wastewater treatment plant was used as a model of cultivated soil that had been used for a long period of time and had weak geological strength.
Using fermented soil mixed with cultured soil amendment material A containing 50 g of artificial zeolite per kg of sludge, fertilizer with fertilizer as chemical fertilizer (containing 8% nitrogen, 8% phosphoric acid, 8% potassium) by weight per planter Then, cherry tomatoes were cultivated. As conditions at the time of cultivation, the planter of 90 cm x 30 cm was used under the temperature of 20-28 degreeC, and the number of the seedlings to transplant was set to three.
As Comparative Examples 1 and 2, two culture soils containing no artificial soil improvement material A containing artificial zeolite were also prepared. In Comparative Example 1, a chemical fertilizer (8% nitrogen, 8% phosphoric acid, 8% potassium by weight%) was used as a basic fertilizer. %) Was fertilized at 80 g per planter. A cherry tomato seedling was transplanted in each of the soils of Comparative Examples 1 and 2 in the same manner as in Example 2 and cultivated. In Example 2 and Comparative Examples 1 and 2, water was supplied every day.
After 70 days, in Example 2, there was an average of 24.4 ripe cherry tomatoes per strain, whereas in Comparative Example 1, only an average of 7.6 immature cherry tomatoes could be harvested per strain, The seedling of Comparative Example 2 died.

As the original fertilizer, the culture soil is composed of 4% by weight, culture soil improvement material A4% containing artificial zeolite, 20% bark compost, 20% akadama soil, 20% pumice, 14% peat moss, 10% coco pate, 12% pearlite. Chemical fertilizer (containing 8% nitrogen, 8% phosphoric acid, 8% potassium by weight)
The planter was fertilized with 80 g and viola was cultivated. As conditions at the time of cultivation, the planter of 90 cm x 30 cm was used under the temperature of 0-15 degreeC, and the number of the seedlings to transplant was set to ten.
As Comparative Example 3, a culture soil containing no artificial zeolite was prepared, and a chemical fertilizer (containing 8% by weight, nitrogen 8%, phosphoric acid 8%, potassium 8%) as a fertilizer was fertilized at a rate of 80 g per planter. Were transplanted and cultivated in the same manner as described above.
The diameter (maximum diameter) and height of each strain were measured on the 20th, 40th, 60th, 80th, and 130th days after seedling transplantation. The results are shown in Table 2. The number of flowers on day 130 was 149 in Example 3 and 63 in Comparative Example 3.

As the original fertilizer, the culture soil is composed of 4% by weight, culture soil improvement material A4% containing artificial zeolite, 20% bark compost, 20% akadama soil, 20% pumice, 14% peat moss, 10% coco pate, 12% pearlite. Chemical fertilizer (containing 8% by weight of nitrogen, 8% phosphoric acid, 8% potassium) was fertilized by 80 g per planter, and pansy was cultivated. As conditions at the time of cultivation, the planter of 90 cm x 30 cm was used under the temperature of 0-15 degreeC, and the number of the seedlings to transplant was set to ten.
As Comparative Example 4, a cultured soil containing no artificial zeolite was prepared, and a chemical fertilizer (containing 8% by weight, nitrogen 8%, phosphoric acid 8%, potassium 8%) as a fertilizer was fertilized at 80 g per planter, and each soil was pansy. Were transplanted and cultivated in the same manner as described above.
The diameter (maximum diameter) and height of each strain were measured on the 20th, 40th, 60th, 80th, and 130th days after seedling transplantation. The results are shown in Table 3. The number of flowers on day 130 was 84 in Example 4, but 29 in Comparative Example 4.

As the original fertilizer, the culture soil is composed of 4% by weight, culture soil improvement material A4% containing artificial zeolite, 20% bark compost, 20% akadama soil, 20% pumice, 14% peat moss, 10% coco pate, 12% pearlite. Chemical fertilizer (containing 8% nitrogen, 8% phosphoric acid, 8% potassium by weight)
The planter was fertilized with 80 g per planter, and cabbage was cultivated in response to the damage of green caterpillar larvae. As conditions at the time of cultivation, the planter of 90 cm x 30 cm was used under the temperature of 10-20 degreeC, and the number of the seedlings to transplant was set to ten.
As Comparative Example 5, culture soil containing no artificial zeolite was prepared, and cabbage seedlings that were damaged by green caterpillar larvae were transplanted to each soil in the same manner as above, and chemical fertilizer (nitrogen in weight%) was used as the original fertilizer. 8%, containing 8% phosphoric acid and 8% potassium) was applied with 80 g of fertilizer per planter and cultivated.
The diameter (maximum diameter) and height of each strain were measured on the 20th, 40th, 60th, 80th, and 130th days after seedling transplantation. The results are shown in Table 4. According to Table 4, the cabbage of Comparative Example 5 that was damaged by the green worms died as it was, but the cabbage of Example 5 recovered from the damage of the green worms in both roots and leaves after 40 days. Regained the strong leaves.

Using fermented soil mixed with soil-improving material C containing 50 g of artificial zeolite per 1 kg of sludge, chemical fertilizer (containing 8% nitrogen, 8% phosphoric acid, 8% potassium by weight%) as fertilizer and fertilizing 80g per planter Then, spinach was cultivated. As conditions at the time of cultivation, the planter of 90 cm x 30 cm was used under the temperature of 15-20 degreeC, the number of the seedlings to transplant was made into 10, and it cultivated by supplying water every day.
According to the observation on the 60th day after seedling transplantation, the spinach of Example 6 showed the same growth as the spinach of Comparative Example 6, and the size and leaf color were not significantly different from those of Comparative Example 6.

Using fermented soil mixed with cultured soil improving material E containing 50 g of artificial zeolite per kg of sludge, chemical fertilizer (containing 8% nitrogen by weight, 8% phosphoric acid, 8% potassium) as fertilizer and fertilizing 80 g per planter Then, spinach was cultivated. As conditions at the time of cultivation, the planter of 90 cm x 30 cm was used under the temperature of 15-20 degreeC, the number of the seedlings to transplant was made into 10, and it cultivated by supplying water every day.
According to the observation on the 60th day after seedling transplantation, the spinach of Example 7 grew larger than the spinach of Comparative Example 6.

  Using fermented soil mixed with soil improvement material F containing 50 g of artificial zeolite per 1 kg of sludge, fertilizer with fertilizer as raw fertilizer (containing 8% nitrogen, 8% phosphoric acid, 8% potassium) per planter Then, spinach was cultivated. As conditions at the time of cultivation, the planter of 90 cm x 30 cm was used under the temperature of 15-20 degreeC, the number of the seedlings to transplant was made into 10, and it cultivated by supplying water every day. According to observation on the 60th day after seedling transplantation, the spinach of Example 8 grew larger than the spinach of Comparative Example 6, and the leaf color was darker than the spinach of Comparative Example 6.

[Comparative Example 6]
Using the same cultured soil as in Comparative Example 3, chemical fertilizer (containing 8% by weight, nitrogen 8%, phosphoric acid 8%, potassium 8%) as fertilizer was fertilized in an amount of 80 g per planter, and spinach seedlings were applied to each soil as described above. Transplanted in the same way and cultivated spinach. As conditions at the time of cultivation, the planter of 90 cm x 30 cm was used under the temperature of 15-20 degreeC, and the number of the seedlings to transplant was set to ten. Cultivation was carried out by supplying water every day.

[Comparative Example 7]
Using dried sludge, spinach was cultivated without giving fertilizer. As conditions at the time of cultivation, the planter of 90 cm x 30 cm was used under the temperature of 15-20 degreeC, the number of the seedlings to transplant was made into 10, and it cultivated by supplying water every day. The seedlings died without growing.

Claims (3)

Culture iodine improvement material you; and a artificial zeolite and organic fertilizers containing unburned carbon from 3 to 10 wt% of activated carbon like. Potting improvement material according to claim 1, further comprising a ferrous water soluble ions (Fe ^2-) salts and / or ferric ion (Fe ^3-) salts. A culture soil improving material according to claim 1 or 2, and one or more soils selected from pumice, peat moss, coco pate, compost, perlite, akadama soil, humus soil, vermiculite, bark, bark compost, eggplant, and charcoal. , including the artificial zeolite and organic fertilizer which is characterized in that a mixture of culture iodide.