JP2014113128A - Method for metal coating of seed and metal-coated seed - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve a metal-coated seed.SOLUTION: A method for metal coating of a seed which coats a seed by causing metal powder composed mainly of iron to adhere to the seed comprises a process of metal coating which causes metal powder to adhere to a seed to form an outermost layer.

Description

  The present invention relates to a seed metal coating method and a metal-coated seed in which a metal powder mainly composed of iron is attached to a seed to coat the seed.

  Since direct seeding cultivation of rice can eliminate the seedling and rice planting operations, it is expected that the labor can be greatly reduced, the use materials can be reduced, and the cost of rice cultivation can be reduced.

  In the direct sowing cultivation, it is known to coat rice seeds with iron. Iron-coated seeds have a high specific gravity, so that the seeded state is less likely to be disturbed by rainwater or incoming water, and a hard shell of iron coating is formed, which is highly resistant to bird damage. Moreover, since seeding is carried out on the soil surface, seed emergence is improved. Since the iron-coated seeds can be stored for a long period of time, the operation of coating rice seeds with iron can be carried out during the agricultural off-season or the like, and the period until sowing can be stored in an iron-coated state.

  Iron-coated seeds must satisfy the following conditions. That is, the seeds sowed will come into contact with water and should not collapse in an environment where the iron coating is in contact with water. In addition, since rice seeds are sown using a machine such as a seeding machine, they must have strength characteristics that do not collapse due to mechanical impact. Further, when the iron coating layer is peeled off, it may cause wear of a machine such as a seeder, so that it is necessary to prevent peeling of the iron coating layer.

  Iron-coated seeds are usually coated with iron powder and calcined gypsum as an oxidation accelerator and sprayed with water. Furthermore, calcined gypsum is coated as a finishing layer in order to reinforce the iron coating layer and prevent peeling of the iron powder (for example, Non-Patent Document 1).

Iron-coated flooded direct sowing manual 2010, National Institute of Agricultural and Food Research Kinki Chugoku-Shikoku Agricultural Research Center, 2011.03

  As described above, in the iron-coated seeds described in Non-Patent Document 1, the finish of the calcined gypsum is formed to prevent the iron coating layer from collapsing and the wear of a machine such as a seeding machine. Yes. However, further improvements are desired from the viewpoint of further improving work efficiency and reducing costs.

  The seed metal coating method according to the present invention is a seed metal coating method in which a metal powder mainly composed of iron is attached to a seed to coat the seed, and the metal powder is attached to the seed. And a metal coating process for forming the outermost layer.

  Conventionally, as described in Non-Patent Document 1, etc., a finishing layer made of calcined gypsum has been formed in order to prevent the metal powder from peeling from the coating layer. Thereby, it was thought that peeling of the metal powder from the coating layer was prevented, so that the collapse of the metal coating layer and the wear of a machine such as a seeder by the peeled metal powder could be prevented.

  However, as shown in the following [Experimental Example 1], the inventors of the present invention formed a finishing layer when a metal powder was attached to seeds to form an outermost layer (that is, a finishing layer was not formed). It has been found that the particle diameter of the peeled metal powder is smaller than that in the case where it is formed. Further, when the outermost layer is formed by attaching the metal powder to the seed (that is, the finish layer is not formed), the weight of the peeled metal powder does not change much compared to the case where the finish layer is formed. I found out.

  In general, it is metal powder having a relatively large particle size that affects the wear of a machine such as a seeder. For this reason, since the particle diameter of the metal powder which peels becomes small by not providing a finishing layer in a metal coating seed, it can aim at prevention of abrasion of machines, such as a seeder.

  Moreover, even when the finishing layer is not formed, the weight of the peeled metal powder does not change so much as compared with the case where the finishing layer is formed. It is considered that the seed is coated with the metal powder in the same manner as in the case of forming. For this reason, even when the finishing layer is not formed, the metal coating layer can be prevented from collapsing as in the case where the finishing layer is formed.

  Accordingly, it is possible to further prevent wear of a machine such as a seeder while preventing the iron coating layer from collapsing.

  Here, “having iron as a main component” means that the metal powder contains 50% or more of metal iron. Since the metal powder contains iron as a main component, when the metal powder is attached to the seed, the oxidation reaction of the iron proceeds by moisture contained in the seed or moisture provided from the outside. Rust is generated by the oxidation reaction, and the iron powder is adhered and solidified to the rice seed by this rust, and the seed can be coated with the metal powder.

  In the above method, it is preferable that the seed is coated with a mixture of the metal powder and the holding substance in the metal coating step.

  In the metal coating process, the seed is coated with a mixture of the metal powder and the holding substance, so that the holding substance is present in the layer formed in the metal coating process. As a result, the metal powder can be held more reliably.

  In the above method, it is preferable to perform a pre-coating step of attaching a holding substance capable of holding the metal powder to the surface of the seed prior to the metal coating step.

  Since the holding material capable of holding the metal powder is attached to the seed in the pre-coating process, even if the particle size of the iron powder as the main component of the metal powder is somewhat large, the iron powder attached to the seed It can be held securely. Further, even if there is an uneven portion on the surface of the seed, it can be expected that the surface of the seed is smoothed by the retention substance adhering in the recess. For this reason, since iron powder adheres and is held on the surface of the smoothened seed, the metal powder can be reliably held.

  In the above method, it is preferable that the holding substance is an oxidation accelerator that promotes oxidation of the metal powder.

  By using a substance that functions as an oxidation accelerator as the holding substance, it is not necessary to prepare an oxidation accelerator separately in order to promote the oxidation of the metal powder. As a result, the cost for producing metal-coated seeds can be reduced.

  In the above method, it is preferable that the holding substance is a powder.

  By using a powder as the holding material in the same manner as the metal powder in the metal coating process, the pre-coating process can be performed by the same operation as in the metal coating process. For this reason, a pre-coating process and a metal coating process can be performed with the same apparatus, and the cost of the apparatus at the time of producing a metal coating seed can be reduced.

  In the above method, the holding substance is preferably calcined gypsum.

  By using calcined gypsum as a holding substance, iron powder can be suitably held on the seed surface. Furthermore, calcined gypsum is a material that is also suitable as an oxidation accelerator. Therefore, in the metal coating process, calcined gypsum is used as a retaining material when a mixture of a metal powder mainly composed of iron powder and a retaining material is coated. As a result, the mixed calcined gypsum effectively promotes the oxidation of the iron powder. As a result, the seed can be reliably coated with the metal powder.

  In the above method, it is preferable to use a seed that has been subjected to a soaking step for moistening the seed as the seed.

  In general, the dipping process is performed for the purpose of shortening the number of days of budding after sowing. By performing the subsequent process after the soaking process, the subsequent process can be performed with the seed surface moist. For this reason, metal powder and a holding | maintenance substance can be reliably made to adhere to the surface of a seed with the adhesive force of water. As a result, the seed can be reliably coated with the metal powder.

  In the above method, it is preferable that a weight ratio of the metal powder to the seed is 0.2 to 0.6.

  By setting the weight ratio of the metal powder to the seed to 0.2 to 0.6, the seed can be suitably coated.

  The metal-coated seed according to the present invention includes a seed and a metal layer formed by coating a metal powder mainly composed of iron on the outer periphery of the seed, and the metal layer is the outermost layer.

  With this configuration, as described above, it is possible to further prevent wear of a machine such as a seeder while preventing the metal layer from collapsing.

  As described above, “mainly iron” means that the metal powder contains 50% or more of metallic iron. Since the metal powder is mainly composed of iron, rust is generated by the oxidation reaction of iron, and this rust causes the iron powder to adhere and solidify on the seed, so that the seed is coated with the metal powder. ing.

  The said structure WHEREIN: It is suitable when the said metal layer contains the holding | maintenance substance which can hold | maintain the said metal powder.

  With the above configuration, the metal powder can be reliably held by the holding substance in the metal layer.

  In the above configuration, it is preferable that the density of the metal powder in the predetermined region on the surface side is set smaller than the density of the metal powder in a region outside the predetermined region in the vicinity of the surface of the seed. is there.

  With this configuration, a large amount of the holding substance is present in a predetermined region from the seed surface, and a large amount of the metal powder is present on the outside thereof. For this reason, seed coating with metal powder is performed in a state where the metal powder is securely held on the surface of the seed via the holding substance. As a result, peeling of the metal powder can be effectively prevented.

  In the above configuration, it is preferable that the holding substance is an oxidation accelerator that promotes oxidation of the metal powder.

  By using a substance that functions as an oxidation accelerator as the holding substance, it is not necessary to prepare an oxidation accelerator separately in order to promote the oxidation of the metal powder. As a result, the cost for producing metal-coated seeds can be reduced.

  The said structure WHEREIN: It is suitable in the said holding | maintenance substance being calcined gypsum.

  By using calcined gypsum as a holding substance, iron powder can be suitably held on the seed surface. Furthermore, calcined gypsum is a material that is also suitable as an oxidation accelerator, so when coating a mixture of a metal powder based on iron powder and a retaining material, it is mixed by using calcined gypsum as the retaining material. The calcined gypsum effectively promotes the oxidation of iron powder. As a result, the seed can be reliably coated with the metal powder.

It is the schematic which shows an example of the metal coating seed of this invention. It is the schematic which shows an example of the metal coating seed of this invention. It is a flow which shows each process of an example of the metal coating method of the seed of this invention. It is the schematic which shows the seed in each process of the metal coating method of the seed of this invention. It is a flow which shows each process of an example of the metal coating method of the seed of this invention. It is a photograph of the metal coating seed of Example 1 of this invention. It is a photograph of the metal coating seed of Example 2 of this invention. 2 is a photograph of metal-coated seeds of Comparative Example 1. 3 is a photograph of metal-coated seeds of Comparative Example 2. 2 is a photograph of a release powder from a metal-coated seed in Example 1. 2 is a photograph of a release powder of metal-coated seeds and the like in Comparative Example 1.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(Metal-coated seed)
As shown in FIG. 1, the metal-coated seed 10 of the present invention includes a seed 1, a retention material layer 2 formed on the surface of the seed 1, and a metal layer 3 formed outside the retention material layer 2. That is, the metal layer 3 as the outermost layer is formed on the surface of the metal coated seed 10.

  As the seed 1, for example, plant seeds such as rice seeds and wheat seeds are used. As the rice seed varieties, japonica and indica can be used. The metal-coated seed 10 obtained by applying a metal coating to the seed 1 has a high specific gravity and sinks in the water, so that it is difficult to flow with water after sowing, and a metal-coated hard shell is formed, which is resistant to bird damage. have. When it is desired to impart such characteristics to a desired seed, the metal-coated seed of the present invention can be applied to any seed. Hereinafter, this embodiment demonstrates the case where a rice seed is used.

  The metal-coated seed 10 can be used for direct sowing cultivation. The time for performing the metal coating is not particularly limited as long as it is before sowing such as direct sowing, such as in the agricultural free season.

  The holding substance used for the holding substance layer 2 is not particularly limited as long as the metal powder can be held on the seed during coating. For example, a powdery substance, a paste-like substance, or the like can be used. As the powdery substance, for example, calcined gypsum, calcium peroxide, wheat flour, potato starch and the like can be applied as long as they can agglomerate to some extent by moisture and form a layer around seeds. A part of the metal powder is buried in the layer formed around the seed, whereby the metal powder is held around the seed. As the paste-like substance, for example, a paste such as starch paste or chemical paste can be used. Due to the adhesive strength of these pasty substances, the metal powder described below can be adhered and held around the seeds.

  In addition, when a corrosive substance such as wheat flour, potato starch, starch paste or the like is used as the holding substance, it is necessary to take precautions such as disinfecting the seeds beforehand in order to prevent the propagation of germs and mold. Also, the humidity and temperature when storing the metal-coated seed 10 need to be strictly managed for the same reason.

  The metal powder used for the metal layer 3 is made to contain iron as a main component. In this specification, “mainly iron” means that the metal powder contains 50% or more, preferably 70% by weight or more of metallic iron. As described above, when the metal powder contains iron as a main component, the oxidation reaction of iron can surely proceed in the presence of water.

  In addition to the iron powder, the metal powder may contain, for example, a metal other than iron or a nonmetal such as oxygen, carbon, sulfur, or silicon dioxide. The iron powder of the metal layer 3 is in a state where all or most of the iron powder undergoes an oxidation reaction by moisture contained in seeds or moisture provided from the outside, and rust is generated.

  In addition, you may form the metal layer 3 with the mixture which mixed the oxidation promoter with the metal powder. Although it does not specifically limit as an oxidation promoter, For example, calcined gypsum, calcium peroxide, potassium sulfate, magnesium sulfate, potassium chloride, calcium chloride, magnesium chloride etc. can be used. Thus, the oxidation of iron powder can be reliably advanced by mixing an oxidation accelerator with metal powder. In particular, if a substance that functions as the holding substance is selected as the oxidation accelerator, the metal powder can be held in the metal layer, and the coating strength of the metal layer 3 is increased. As such a substance, calcined gypsum is particularly preferable.

  By using calcined gypsum as a holding substance, iron powder can be suitably held on the seed surface. For this reason, since the coating strength can be increased even with a small amount of iron powder, the amount of metal powder to be used can be reduced. Furthermore, since calcined gypsum is a suitable material as an oxidation accelerator, by using calcined gypsum as a holding substance, the mixed calcined gypsum effectively promotes the oxidation of iron powder. As a result, it is possible to obtain a metal-coated seed having high coating strength in which the iron powder is reliably attached to the seed due to the rust of the iron powder.

  Thus, by using calcined gypsum for both the retention material layer 2 and the metal layer 3, the cost for producing metal-coated seeds can be reduced. That is, as described above, calcined gypsum has been suitably used as an oxidation accelerator in conventional metal-coated seeds. Therefore, it is not necessary to newly prepare a substance for the holding layer.

In addition, calcined gypsum (CaSO ₄ · 1 / 2H ₂ O) is a powdery substance as described above, but becomes gypsum (CaSO ₄ · H ₂ O) and solidifies by the following reaction.
CaSO ₄ · 1 / 2H ₂ O + 1 / 2H ₂ O → CaSO ₄ · H ₂ O
For this reason, by using calcined gypsum for the holding layer 2 and the metal layer 3, the effect of holding the metal powder more reliably by solidifying a part of the calcined gypsum by the above reaction in each layer and between layers. Therefore, it can be expected to prevent metal powder from being pulverized when producing metal-coated seeds.

  As described above, in the example shown in FIG. 1, in the vicinity of the surface of the seed 1, the density of the metal powder is smaller than the density of the metal powder in the metal layer 3 outside the predetermined area in the surface area. A set retention material layer 2 is formed. In addition, in FIG. 1, although the case where the whole surface of the seed 1 was typically covered with the holding | maintenance substance layer 2 and the metal layer 3 was formed in the outer side was demonstrated to the example, for example, a part of metal powder is It may be buried in the retaining material layer 2 and in direct contact with the surface of the seed 1.

  The retention material layer 2 is not necessarily provided, and the metal layer 3 may be provided directly on the surface of the seed 1 as shown in FIG. 2, and the metal layer 3 may be the outermost layer. That is, the metal coated seed 10 of the present invention only needs to have the metal layer 3 as the outermost layer, and may or may not have other inner layers.

  Thus, since the metal layer 3 exists as the outermost layer, a strong layer is formed by the rust generated by the oxidation reaction of iron, and therefore there is a strong layer as the outermost layer of the seed 1. Become.

(Seed metal coating method)
An example of the metal coating method for seeds of the present invention will be described by taking as an example the case of producing the metal coated seeds shown in FIG. 1 using rice seeds.
As shown in FIGS. 3 and 4, the seed 1 metal coating method includes a soaking process, a pre-coating process, a metal coating process, an oxidation process, and a drying process. Details of each step will be described below.

  The seed 1 is preferably subjected to a soaking process in which the seed 1 is soaked in water before coating. Although not particularly limited, the temperature of water used in the soaking process is preferably about 15 to 20 ° C., and the soaking time is preferably about 3 to 4 days. Although not particularly limited, the integrated temperature in the soaking process is preferably about 40 ° C. to 60 ° C., and the temperature of the water used in the soaking process and the soaking time may be set so that the integrated temperature becomes like this.

A pre-coating process is performed after the soaking process.
In the pre-coating step, the seed 1 is put into a granulator. At this time, if necessary, moisture may be supplied to the seed 1 by a sprayer or the like. Furthermore, a holding substance is put into the granulator. These are mixed with stirring in a granulator, and water is sprayed as appropriate to adhere the retention substance to the seed surface (FIG. 4 (b)). Thereby, the retention substance layer 2 is formed on the surface of the seed 1. At this time, the holding substance 21 enters the recesses present on the surface of the seed 1, thereby smoothening the surface of the seed 1 and facilitating the adhesion of the metal powder in the subsequent metal coating process.

  The retaining substance is not particularly limited as long as it is the above, but calcined gypsum is particularly suitable. When calcined gypsum is used as the holding substance, it is not particularly limited, but the ratio of calcined gypsum is preferably about 0.5 to 2 wt% with respect to the dry weight of the seed (the weight of the seed before the dipping process). Preferably it is about 1 wt%.

  The pre-coating process may be performed immediately after the soaking process, or may be performed after some time from the soaking process, for example, after several days. When the pre-coating step is performed immediately after the soaking step, it may be performed after draining. When the pre-coating process is performed after a lapse of time from the soaking process, it is preferable that the moisture content be about 15% or less by natural drying or ventilation drying before storage.

A metal coating process is performed after the pre-coating process.
In the metal coating process, a mixture of the metal powder and the oxidation accelerator is put into a granulator after completion of the pre-coating process. These are mixed with stirring in a granulator, and water is sprayed as appropriate to attach the metal powder and the oxidation accelerator to the surface of the seed 1 (holding substance layer 2) after the pre-coating step (FIG. 4 ( c)). Thereby, the metal layer 3 as the outermost layer is formed outside the holding material layer 2.

  The metal powder is not particularly limited as long as it is the above, but iron powder can be used. The oxidation accelerator is not particularly limited as long as it is as described above, but calcined gypsum is preferably used. In the metal coating step, when the coating is performed with a mixture of iron powder and calcined gypsum, there is no particular limitation, but the ratio of the iron powder may be 20 to 40 wt% with respect to the dry weight of the seed 1, and is preferable. Is 25-35 wt%. Especially preferably, it is about 30 wt%.

  Although not particularly limited, the ratio of calcined gypsum is preferably 1.5 to 3.5 wt%, particularly preferably about 2.5 wt%, with respect to the dry weight of seed 1. Moreover, when coating with the mixture of iron powder and calcined gypsum, the ratio of calcined gypsum with respect to the iron powder in a mixture is good to set it as 7-10 wt%, Most preferably, it is 8-9 wt%.

After the metal coating process, an oxidation / drying process is performed.
The oxidation / drying step is performed, for example, by transferring the seed 1 after the finish coating step to, for example, a seedling box for mat seedling growth. In the oxidation / drying step, water is appropriately supplied to the seeds 1 in the seedling box by spraying or the like. Thereby, oxidation and drying by oxidation heat are repeated, and the oxidation reaction of iron in the metal powder proceeds by the action of water and calcined gypsum as an oxidation accelerator. Rust is generated by the oxidation reaction of iron, and the iron powder is aggregated by the rust, so that the surface of the seed is covered with the metal layer 3 made of strong iron oxide. Thereafter, the seed is dried by, for example, ventilating the seed with a fan or the like. Thereby, the metal coating seed 10 is completed. In addition, you may ventilate with a fan etc. throughout the oxidation / drying process.

  As described above, in the metal-coated seed 10 of the present invention, the retention material layer 2 is not essential, and when the retention material layer 2 is not provided on the metal-coated seed 10 (see FIG. 2), as shown in FIG. In addition, the pre-coating process is omitted. That is, a metal coating process is performed on the seed 1 after the soaking process.

  Even when the pre-coating step is not performed, the metal powder is not particularly limited as long as it is the above, but iron powder can be used. The oxidation accelerator is not particularly limited as long as it is as described above, but calcined gypsum is preferably used. In the metal coating process, when coating is performed with a mixture of iron powder and calcined gypsum, there is no particular limitation, but the ratio of the iron powder may be 40 to 60 wt% with respect to the dry weight of the seed 1, and is preferable. Is 45-55 wt%. Especially preferably, it is about 50 wt%.

  Although not particularly limited, the ratio of calcined gypsum is preferably 4 to 6 wt%, particularly preferably about 5 wt%, with respect to the dry weight of seed 1. Moreover, when coating with the mixture of iron powder and calcined gypsum, the ratio of calcined gypsum with respect to the iron powder in a mixture is 8-12 wt%, Most preferably, it is about 10 wt%.

  In addition, although it does not specifically limit as a granulation apparatus used in the said process, For example, the coating machine KC-151 by a Keibunsha Seisakusho Co., Ltd. can be used suitably.

Below, the Example of the metal coating seed of this invention is described.
In Example 1, rice seeds (Koshihikari: japonica seeds) were coated by performing the dipping process, the metal coating process, the oxidation process, and the drying process according to the above procedure. As the coating machine, KC-151 manufactured by Keibunsha Seisakusho Co., Ltd. was used. In each Example, the said process was performed with respect to 1000g of seeds before immersion.
Example 2 differs from Example 1 in that a pre-coating process is performed between the dipping process and the metal coating process in addition to the above process.

  The coating materials and weights applied to each step of each example are as follows. In each example, DAE1K manufactured by DOWA IP Creation Co., Ltd. was used as the iron powder.

[Example 1] (based on 1000 g of seed before immersion)
Metal coating process: mixture of iron powder 500g and calcined gypsum 50g

[Example 2] (based on 1000 g of seed before immersion)
Pre-coating process: calcined gypsum 10g
Metal coating process: mixture of iron powder 300g and calcined gypsum 25g

[Comparative Example]
Below, the comparative example of the metal coating seed of this invention is demonstrated.
In Comparative Example 1, a metal-coated seed was prepared by performing a dipping process, a metal coating process, a finish coating process, an oxidation process, and a drying process. That is, it differs from Example 1 above in that finish coating is performed after the metal coating step.

  Moreover, in the comparative example 2, the immersion process, the pre-coating process, the metal coating process, the finish coating process, the oxidation process, and the drying process were performed, and the metal coating seed was created. That is, it differs from Example 2 above in that finish coating is performed after the metal coating process.

  In Comparative Example 1 and Comparative Example 2, the finish coating was performed according to the following procedure. That is, calcined gypsum is put into the granulator after the metal coating process. These are mixed with stirring in a granulator, and water is sprayed as appropriate to allow calcined gypsum to adhere to the surface (metal layer) of the seed after the metal coating process. Thereby, a finishing layer was formed outside the metal layer. After the finish coating step, an oxidation step was performed by the same procedure as described above.

[Comparative Example 1] (based on 1000 g of seed before immersion)
Metal coating process: Mixture of 500 g of iron powder and 50 g of calcined gypsum Finishing process: 25 g of calcined gypsum

[Comparative Example 2] (based on 1000 g of seed before immersion)
Pre-coating process: calcined gypsum 10g
Metal coating process: mixture of iron powder 300g and calcined gypsum 25g Finishing process: calcined gypsum 10g

  6 to 10 show photographs of the respective metal-coated seeds. 6 is a metal-coated seed according to Example 1, FIG. 7 is a metal-coated seed according to Example 2, FIG. 8 is a metal-coated seed according to Comparative Example 1, and FIG. 9 is a metal-coated seed according to Comparative Example 2. is there. From FIG. 6 to FIG. 10, it can be seen that seeds are reliably coated in any metal coating layer.

[Experimental Example 1]
Using the metal-coated seeds after the drying process in Examples 1 and 2 and Comparative Examples 1 and 2 described above, a coating layer peeling experiment was performed. In the experiment, the metal-coated seeds placed in a net bag were dropped 10 times each from a location with a height of 20 cm and a height of 50 cm. Thereafter, the net bag was shaken 10 times to the left and right to give friction to the metal coated seeds. Thereafter, the exfoliated powder exfoliated from each metal coated seed was collected and weighed. Moreover, the property of peeling powder was observed.

The weight of the release powder and the release ratio of each Example and Comparative Example were as follows. The exfoliation ratio was expressed as a percentage of the exfoliated powder weight relative to the total weight of the seed (dry weight) and the iron powder and calcined gypsum coated in each step.
Example 1: Release powder weight 21.61 g Peel rate 4.3%
Example 2: Release powder weight 12.46 g Release rate 4.2%
Comparative Example 1: Release powder weight 17.68 g Release rate 3.5%
Comparative Example 2: Release powder weight 9.50 g Peel rate 3.2%

  FIG. 10 shows a photograph of the release powder in Example 1, and FIG. 11 shows a photograph of the release powder in Comparative Example 1.

  As is clear from the above, when the weight of peeled powder (peeling ratio) in Example 1 and Comparative Example 1 was compared, the weight of the peeled powder in Example 1 was 21.61 g (peeling rate was 4.3%). The peeled powder weight of Comparative Example 1 was slightly higher than 17.68 g (peeling rate was 3.5%). On the other hand, as is clear from FIGS. 10 and 11, the ratio of the exfoliated powder having a large particle size was much smaller in Example 1.

  Also, in the comparison between Example 2 and Comparative Example 2, the weight of release powder of Example 2 was 12.46 g (peeling rate was 4.2%), and the weight of peeling powder of Comparative Example 2 was 9.50 g (peeling rate). Slightly exceeded 3.2%). On the other hand, although not shown, the ratio of the release powder having a large particle size was much smaller in Example 2 as in the comparison between Example 1 and Comparative Example 1 above.

  That is, by not providing the finishing layer (by making the metal layer 3 the outermost layer), the weight of the release powder is slightly increased, but the amount of release of the release powder having a large particle size is greatly reduced. confirmed.

  Generally, it is metal powder (peeling powder) having a relatively large particle size that affects the wear of a machine such as a seeder. For this reason, since the particle diameter of exfoliation powder becomes small by not providing a finishing layer in metal coating seed, it can aim at prevention of wear of machines, such as a seeder.

  In addition, even when the finishing layer is not formed, the weight of the release powder does not change much compared to when the finishing layer is formed, so the finishing layer is formed even when the finishing layer is not formed. It is considered that the seed is coated with the metal layer as in the case of the above. For this reason, even when the finish layer is not formed, the collapse of the metal layer can be prevented as in the case where the finish layer is formed.

In addition, the following points are guessed as a cause of the above result. That is, as described above, calcined gypsum (CaSO ₄ .1 / 2H ₂ O) becomes gypsum (CaSO ₄ .H ₂ O) and solidifies. For this reason, when the finish coating layer is provided as in the metal coated seeds of Comparative Example 1 and Comparative Example 2, the calcined gypsum contained in both layers is solidified between the finish layer and the metal layer. Interaction is considered to work.

  Here, the finished layer formed by solidifying calcined gypsum has lower strength against impacts etc. than the metal layer made of strong iron oxide, and when the outermost layer is the finished layer, the outermost layer is compared with the metal layer. Therefore, it is considered that the finished layer is easily peeled off. As a result of the interaction between the finish layer and the metal layer, it is considered that even with the finish layer peeling, even the iron powder that is relatively oxidized and increased in size in the metal layer is peeled off together with the finish layer. .

  On the other hand, when the outermost layer is a metal layer, the iron powder in the metal layer, which has been relatively oxidized and increased, does not exfoliate so much, and mainly the small iron powder that has not progressed as much as exfoliated. Conceivable.

  For this reason, in Example 1 and Example 2, compared with the comparative example 1 and the comparative example 2, it is thought that the ratio of the comparatively big peeling powder contained in peeling powder became very small.

[Experiment 2]
Next, the experimental result which compared the germination vigor of each metal coating seed is shown.
In the experiment, using the metal-coated seeds of Example 1 above, the metal-coated seeds of Example 2, the metal-coated seeds of Comparative Example 1, the metal-coated seeds of Comparative Example 2, and the raw rice without coating, The sprouting vigor of the offspring was compared. In addition, the integrated temperature (total with the integrated temperature at the time of a soaking process) until the length of the bud in each child reached 10 mm was applied as a parameter | index which shows germination vigor. Hereinafter, this integrated temperature is referred to as “10 mm integrated temperature”.

  Rice seeds (Koshihikari: japonica seeds) were subjected to a soaking process until an integrated temperature of 60 ° C. was reached (at 20 ° C. for 72 hours), and thereafter, each process after the soaking process was performed to produce each metal-coated seed. In addition, about the raw material, each process after a soaking process was not performed but the experiment demonstrated below was conducted.

A germination test was performed on each metal-coated seed and silkworm in an environment with a water temperature of 20 ° C., and the accumulated temperatures of 10 mm were compared. The integrated temperature is generally calculated based on the following equation.
Integrated temperature (° C) = soaking temperature (° C) x sowing time (h) / 24 (h)
Therefore, in this experiment, the integrated temperature was calculated by the following equation.
10mm integrated temperature (℃)
= 60 (° C) + 20 ° C × Time required for germination test (h) / 24 (h)

The 10 mm integrated temperature in each seed is shown below.
Example 1: 220 ° C
Example 2: 180 ° C
Comparative Example 1: 230 ° C
Comparative Example 2: 190 ° C
Natural: 180 ℃

  As can be seen from the above results, in any of the examples and comparative examples, the accumulated temperature (time) until the length of the buds reached 10 mm was slightly increased as compared with the raw material, but there was no significant increase. It was in a range where there was no problem in practical use.

  Further, as can be seen from the above results, in either case of Example 1 or Example 2, by not providing a finishing layer, the accumulated temperature (time) until the bud length reaches 10 mm is slightly increased. There was a decrease. Therefore, from this experiment, an effect of reducing the required integrated temperature until germination is expected as a secondary effect by making the metal layer 3 the outermost layer.

  The material of the present invention can be used as a method for metal coating of rice and other seeds and as a metal-coated seed.

DESCRIPTION OF SYMBOLS 1 Seed 2 Retention substance layer 3 Metal layer 10 Metal coating seed 21 Retention substance

Claims (13)

A seed metal coating method for coating a seed by attaching a metal powder mainly composed of iron to the seed,
A seed metal coating method comprising a metal coating step of forming an outermost layer by attaching the metal powder to the seed.   The seed metal coating method according to claim 1, wherein in the metal coating step, the seed is coated with a mixture of the metal powder and a holding substance capable of holding the metal powder.   The seed metal coating method according to claim 1 or 2, wherein a pre-coating step of attaching a holding substance capable of holding the metal powder to the surface of the seed is performed prior to the metal coating step.   The seed metal coating method according to claim 2, wherein the holding substance is an oxidation accelerator that promotes oxidation of the metal powder.   The seed metal coating method according to any one of claims 2 to 4, wherein the holding substance is powder.   The seed metal coating method according to any one of claims 2 to 5, wherein the holding substance is calcined gypsum.   The seed metal coating method according to any one of claims 1 to 6, wherein a seed subjected to a soaking step for moistening the seed is used as the seed.   The seed metal coating method according to any one of claims 1 to 7, wherein a weight ratio of the metal powder to the seed is 0.2 to 0.6. Seeds,
A metal layer formed by coating a metal powder containing iron as a main component on the outer periphery of the seed;
Metal-coated seed in which the metal layer is the outermost layer.   The metal-coated seed according to claim 9, wherein the metal layer contains a holding substance capable of holding the metal powder.   The metal according to claim 10, wherein a density of the metal powder in a predetermined region on the surface side is set smaller than a density of the metal powder in a region outside the predetermined region in the vicinity of the surface of the seed. Coated seeds.   The metal-coated seed according to claim 10 or 11, wherein the holding substance is an oxidation accelerator that promotes oxidation of the metal powder.   The metal-coated seed according to any one of claims 10 to 12, wherein the holding substance is calcined gypsum.