JP2013183695A - Method for cultivating potato, fuel using potato, and potato cultivating tool - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for cultivating potatoes, capable of increasing an annual production volume by cultivating potatoes and sweet potatoes in a short period, to provide a potato cultivating tool, and to provide fuel using potatoes.SOLUTION: A method for cultivating potatoes includes cultivating potatoes by limiting a rooting zone to a section area 20 with a depth of 10-30 cm, and a horizontal cross-section area of 60-180 cm, or cultivating sweet potatoes by limiting a rooting zone to a section area 20 with a depth of 20-45 cm, and a horizontal cross-section area of 80-200 cm. As a result of this, the root growth of potatoes or sweet potatoes is limited to grow small potatoes of potatoes or sweet potatoes in an early stage.

Description

  The present invention relates to a method for cultivating potatoes that grow potatoes or sweet potatoes, and more particularly to a technique for cultivating potatoes or sweet potatoes in a short period of time to increase the annual production.

  Potatoes such as potatoes and sweet potatoes are used as food or fuel. Here, the main varieties of potato include baron and may queen. The main varieties of sweet potato include red bean and Anno.

  In general, potatoes and sweet potatoes are cultivated by planting rape seedlings in a field (farm) where the rhizosphere is not restricted. At this time, in the cultivation process of potatoes and sweet potatoes, after the roots, stems and leaves are sufficiently grown, the roots or stems in the ground grow as small pods. On the other hand, for example, Patent Literature 1 discloses that the root zone is limited using a polypot or a seedling box when cultivating a bite-sized mini potato.

Japanese Patent Laid-Open No. 11-127712

  However, the technique according to Patent Document 1 only restricts the rhizosphere in order to cultivate small cocoons, and does not aim to produce cocoons in a short period of time. Therefore, in the said patent document 1, the description and suggestion about the value of the depth and area of a rhizosphere suitable for producing a cocoon in a short period are not made | formed.

  Specifically, Patent Document 1 discloses that the size of the polypot is 10.5 cm in diameter, but does not disclose the limitation of the depth. Moreover, although it is disclosed that the size of the seedling box is 510 × 365 × 82 mm, this makes it impossible to produce cocoons in a short period of time because the rhizosphere area is too large and the depth is too small.

  Accordingly, the present invention has been made in view of the above circumstances, and the purpose thereof is to cultivate potatoes or sweet potatoes in a short period of time to increase annual production, and cultivation of strawberries An object is to provide a fuel using a device and a soot.

[Cultivation method of potato]
In order to achieve the above object, the cultivation method of straw according to the present invention is to cultivate potato by limiting the rhizosphere to a partitioned region having a depth of 10 to 30 cm and a horizontal sectional area of 60 to 180 cm ^2. It is a feature.
Thus, when the root zone is restricted by the partition region, the growth of potato roots is saturated at an early stage, and the growth of potatoes is started. Therefore, according to the present invention, it is possible to cultivate potatoes in a short period of time and increase the annual production by restricting root growth and promoting early growth of small potatoes.

By the way, generally, the period required for cultivation of straw is around 20 weeks, and during that period, it is cultivated outdoors receiving sunlight, so that a large-scale field is required outdoors for mass production of straw. On the other hand, it was found that the roots, stems, and leaves of potatoes grew sufficiently even in a certain low illumination environment during the first predetermined period of the potato cultivation period. Specifically, potatoes could be grown until the leaves grew to about 20 to 50 leaves indoors receiving light with an illuminance of 2 k to 10 k [lx].
Then, the cultivation method of the said cocoon is the 1st cultivation process which grows the said potato in the low illumination intensity conditions which satisfy | fill the predetermined low illumination intensity, and the high illumination intensity conditions which predetermined the said potato after the said 1st cultivation process. It is desirable to have the 2nd cultivation process grown in the high illumination environment which satisfies. Thus, the cultivation period in the said high illumination intensity environment can be shortened by making the cultivation process of a potato into the two steps of the said 1st cultivation process and the said 2nd cultivation process from which illumination intensity environment differs.
For example, the low illuminance condition is to receive light with an illuminance of 2 k to 10 k [lx], and the high illuminance condition is to receive light with an illuminance of 40 k to 100 k [lx] or sunlight. That is, in the first cultivation process, an environment for receiving light or sunlight with an illuminance of 40 k to 100 k [lx] is not required. More specifically, it is conceivable that the low illuminance environment is indoor or outdoor shade, and the high illuminance environment is outdoor sunlight.
In this case, since the period of the said 2nd cultivation process which uses the field located in the outdoor sunny direction can be shortened, the annual production amount per unit area of the field can be increased. In other words, mass production of potatoes can be realized by a small outdoor field. Moreover, in the said 1st cultivation process, since it is also possible to carry out in the state with bad sunlight which arranged the said division | segmentation area | region in the vertical direction in multiple steps, the area of the land required for the said 1st cultivation process can be made small. In addition, when performing the said 2nd cultivation process using the artificial illumination which implement | achieves the said high illumination environment, the use period of the artificial illumination can be shortened and power consumption can be saved.

Moreover, the period of the said 1st cultivation process is the 1st range which multiplied the temperature coefficient C calculated by the following (1) formula to the range of 3-6 weeks when the average temperature of cultivation environment is set to T [degreeC]. It is desirable to be within.
C = 1.65-0.027 × T (1)

  By defining the first range in this way, in the first cultivation step, it was possible to grow potatoes moderately until the leaves grew to about 20 to 50. On the other hand, if the period of the first cultivation process is shorter than the first range, the potato leaves are not sufficiently grown, and the period of the second cultivation process becomes unnecessarily long. On the other hand, if the period of the first cultivation step is longer than the first range, the growth rate of potato roots, stems, and leaves is lowered after a certain period of time, so that the production efficiency of straw is lowered.

  Moreover, it is desirable that the period of the second cultivation step is within a second range obtained by multiplying the range of 5 to 8 weeks by the temperature coefficient C. By defining the second range in this way, potatoes could be efficiently cultivated in the second cultivation step. Specifically, it was possible to obtain a high effect in a balanced manner with respect to the amount of potato harvested and the production rate of potato. On the other hand, if the period of the second cultivation step is shorter than the second range, the potato small pods are not sufficiently grown and the yield is reduced. On the other hand, if the period of the second cultivation step is longer than the second range, the growth rate of potato small pods decreases after a certain period of time, so that the production efficiency of cocoons decreases.

  In addition, it is conceivable to grow a plurality of potatoes using a cultivation device for grapes having a plurality of the divided areas partitioned by a partition wall. Thereby, a lot of potatoes can be cultivated using one cultivation implement, and management during cultivation, harvest after cultivation, movement of cultivation place, etc. can be performed easily.

[Growing method of sweet potato]
Moreover, in order to achieve the said objective, the cultivation method of the persimmon which concerns on this invention restrict | limits a rhizosphere to the division area | region whose depth is 20-45 cm and the area of a horizontal cross section is 80-200 cm < ² >, and grows sweet potatoes It is characterized by that.
Thus, when the rhizosphere is restricted by the compartment, the growth of sweet potato roots is saturated at an early stage, and the growth of small sweet potatoes begins. Therefore, according to the present invention, it is possible to cultivate sweet potatoes in a short period of time and increase the annual production by restricting root growth and promoting early growth of small pods.

In addition, the cultivation method of the koji includes a third cultivation process for cultivating the sweet potato in a low illumination environment that satisfies a predetermined low illumination condition, and a predetermined high illumination condition for the sweet potato after the third cultivation process. It is desirable to have the 4th cultivation process grown in the high illumination environment which satisfies. Thus, the cultivation period in the said high illumination intensity environment can be shortened by making the sweet potato cultivation process into two steps of the said 3rd cultivation process and the said 4th cultivation process from which illumination intensity environment differs.
For example, the low illuminance condition is to receive light with an illuminance of 2 k to 10 k [lx], and the high illuminance condition is to receive light with an illuminance of 40 k to 100 k [lx] or sunlight. That is, in the third cultivation step, an environment for receiving light or sunlight with an illuminance of 40 k to 100 k [lx] is not required. More specifically, it is conceivable that the low illuminance environment is indoor or outdoor shade, and the high illuminance environment is outdoor sunlight.
In this case, since the period of the said 4th cultivation process which uses the field located in the outdoor sunny direction can be shortened, the annual production amount per unit area of the field can be increased. In other words, the mass production of sweet potato can be realized by a small outdoor field. Moreover, in the said 3rd cultivation process, since it is also possible to carry out in the state with bad sunlight which arrange | positioned the said division | segmentation area | region in the perpendicular direction, the area of the land required for the said 3rd cultivation process can be made small. In addition, when performing the said 4th cultivation process using the artificial illumination which implement | achieves the said high illumination environment, the use period of the artificial illumination can be shortened and power consumption can be saved.

Moreover, the period of the said 3rd cultivation process is the 3rd range which multiplied the temperature coefficient C calculated by the following (2) formula to the range of 4-8 weeks when the average temperature of cultivation environment is set to T [degreeC]. It is desirable to be within.
C = 1.65-0.027 × T (2)

  By defining the third range in this way, in the third cultivation step, it was possible to grow sweet potatoes moderately until the leaves grew to about 20 to 50. On the other hand, if the period of the third cultivation step is shorter than the third range, the sweet potato leaves are not sufficiently grown, and the period of the fourth cultivation step becomes uselessly long. On the other hand, if the period of the third cultivation step is longer than the third range, the growth rate of sweet potato roots, stems, and leaves is lowered after a certain period of time, so that the production efficiency of koji is lowered.

  The period of the fourth cultivation step is preferably within a fourth range obtained by multiplying the range of 6 to 10 weeks by the temperature coefficient C. Thus, by setting the fourth range, sweet potatoes could be efficiently cultivated in the fourth cultivation step. Specifically, it was possible to obtain a high effect with a good balance between the yield of sweet potato and the production speed of sweet potato. On the other hand, if the period of the fourth cultivation step is shorter than the fourth range, the sweet potato pods are not sufficiently grown and the yield is reduced. On the other hand, if the period of the fourth cultivation step is longer than the fourth range, the growth rate of sweet potato pods decreases after a certain period of time, so that the production efficiency of cocoons decreases.

  Moreover, it is possible to cultivate a plurality of sweet potatoes using a cultivation device for koji having a plurality of the partitioned regions partitioned by a partition wall. Thereby, a lot of sweet potatoes can be cultivated using one cultivation implement, and management during cultivation, harvest after cultivation, movement of a cultivation place, etc. can be performed easily.

[Fuel using soot]
Further, the present invention may be understood as a fuel using a cocoon characterized by being produced from roots, stems, leaves, or small potatoes of potato or sweet potato cultivated by the method for cultivating cocoons. Since the fuel using the straw produced using the straw cultivation method can be mass-produced, it is effective for thermal power generation fuel or biomass liquid fuel (such as ethanol).

[Cultivation equipment for strawberries]
Furthermore, you may catch this invention as invention of the cultivation tool of the cocoon used with the cultivation method of the said cocoon. That is, it can be grasped as a cultivation device for grapes, characterized in that it includes an accommodation part that restricts the root zone of potato to a partitioned region having a depth of 10 to 30 cm and a horizontal cross-sectional area of 60 to 180 cm ² . Moreover, it can be grasped as a cultivation device of a cocoon characterized by including a storage part which restricts the root zone of sweet potato to a partition region having a depth of 20 to 45 cm and a horizontal cross section of 80 to 200 cm ² .
Here, it is conceivable that the accommodating portion has a plurality of the partition regions partitioned by a partition wall. Thereby, a large amount of potatoes or sweet potatoes can be cultivated using one cultivation tool, and management during cultivation, harvesting after cultivation, movement of cultivation place, etc. can be easily performed.
Furthermore, it is desirable that the bottom surface of the housing portion is provided so as to be openable and closable. Thereby, many potatoes or sweet potatoes cultivated in a plurality of the division areas can be easily harvested by removing the bottom surface.

  According to the present invention, potato or sweet potato can be cultivated in a short period to increase the annual production.

The schematic diagram which shows schematic structure of the cultivation implement 1 which concerns on embodiment of this invention. The figure which shows the potato produced by the cultivation method of the cocoon which concerns on this invention. The figure which shows the potato produced by the cultivation method of the cocoon which concerns on this invention. The figure which shows the fuel using the potato and sweet potato which were produced by the cultivation method of the cocoon concerning this invention.

  Embodiments of the present invention will be described below with reference to the accompanying drawings for understanding of the present invention. In addition, the following embodiment is an example which actualized this invention, Comprising: The thing of the character which limits the technical scope of this invention is not.

  Specifically, firstly, the cultivation device 1 for koji and the cultivation method for koji used for cultivation of potato will be described, and then, the cultivation device 2 for koji used for cultivation of sweet potato and the cultivation method for koji.

  Here, the potato produced by the cultivation method of straw according to the present invention is a plant belonging to the genus Solanum, commonly referred to as potato, and has a scientific name of “Solanum tuberosum L.”. For example, potato varieties include Baron, May Queen, Kitaakari, Huang, Andesimo, Decima, Nishiyutaka, Moon Red, Toyoshiro, Waseshiro, Hokorikogane, and the like.

  Moreover, the sweet potato produced by the cultivation method of koji according to the present invention is a plant belonging to the genus Sweet potato family that is generally called sweet potato, and its scientific name is “Ipomoea batatas L.”. For example, varieties of sweet potatoes include red apricot, Anno potato (Anno red, Anno kogane), red potato people, high 14th, red red, Kogane Chinuki, purple tang, orange potato, shiromurasaki, Ayamurasaki, etc. .

[Potato cultivation equipment 1]
FIG. 1: is an external view of the cultivation tool 1 which concerns on this Embodiment, (A) is the perspective view seen from the upper surface side, (B) is the perspective view seen from the bottom face side. As shown to FIG. 1 (A), (B), the said cultivation implement 1 is a container provided with the accommodating part 11 for accommodating the soil and the potato seedling. In addition, the said cultivation instrument 1 may be shape | molded with various materials, such as wood, a plastic resin, an acrylic resin, or a metal.

  The accommodating portion 11 is a rectangular parallelepiped having an open top, and has a plurality of partition regions 20 partitioned by a vertical partition wall 12 and a horizontal partition wall 13. Specifically, the cultivation device 1 is provided with a total of 20 partition regions 20 of 4 rows × 5 rows. Thereby, a lot of potatoes can be cultivated using one cultivation implement, and management during cultivation, harvest after cultivation, movement of cultivation place, etc. can be performed easily.

  In addition, it is possible that the said vertical partition 12 and the said horizontal partition 13 are detachable. As a result, the vertical partition wall 12 and the horizontal partition wall 13 that form a horizontal cross section of an arbitrary size in the accommodating portion 11 can be provided, and the size of each of the partition regions 20 can be arbitrarily changed.

  Further, the bottom of each of the partition regions 20 is constituted by a single bottom surface 14 provided in the accommodating portion 11. The bottom surface 14 is slidably supported by a rail portion (not shown) provided at the lower end portions of the opposing side walls 15A and 15B in the housing portion 11. Accordingly, the bottom portion of the housing portion 11 can be opened and closed by sliding the bottom surface 14 along the rail portion. Thereby, after cultivating potatoes using the cultivating instrument 1, the potatoes cultivated in each of the partition regions 20 of the cultivating instrument 1 by sliding the bottom surface 14 to open the bottom part of the accommodating part 11. Can be easily harvested.

  The method for opening and closing the bottom surface 14 is not limited to the slide method. For example, the bottom surface 14 may be opened and closed by turning around one end, or may be opened and closed by a simple fixture such as a snap fit. Of course, a configuration in which the bottom surface 14 of the accommodating portion 11 is not openable / closable is also conceivable as another embodiment.

Soil and seedlings are accommodated inside each of the partition regions 20. Each of the partition regions 20 is a rectangle (an example of a rectangle) having a horizontal cross section of 8 cm × 10 cm and an area of 80 cm ² , and a depth of 20 cm. Thereby, the root zone of the potato grown with the said cultivation device 1 is restrict | limited by the said division area | region 20 whose depth is 20 cm and whose area of a horizontal cross section is 80 cm < ² >. On the other hand, it is generally known that potato roots spread to about 0.3 to 1 m ³ . Therefore, when potatoes are cultivated using the cultivation device 1, the growth of the roots of the potatoes is restricted by the partition region 20 and saturated early, so that the growth of small potatoes of the potatoes starts at an early stage. .

Here, the size of each partition region 20 is merely an example. Specifically, each of the partition regions 20 may have a depth of 10 to 30 cm and a horizontal cross-sectional area of 60 to 180 cm ² . Moreover, the said cultivation device 1 may be an individual cultivation device which has only one said division area 20. Further, the shape of the horizontal section of each of the partition regions 20 is not limited to a rectangle, but may be a circle, an ellipse, a triangle, a square, a hexagon, or other polygons. However, if the horizontal cross section of the partition region 20 is rectangular, the partition regions 20 can be arranged densely in a limited area without providing a useless space. The root zone can be secured as much as possible.

[Cultivation method of potato]
Hereinafter, the cultivation method of the cocoon for cultivating potato is demonstrated. The cultivation method of the persimmon includes a first cultivation process for cultivating potatoes in a low illuminance environment that satisfies a predetermined low illuminance condition, and a high condition that satisfies a predetermined high illuminance condition for the potatoes after the first cultivation process. It is a two-stage cultivation method which has the 2nd cultivation process grown in illumination intensity environment. In the cultivation method of the persimmon, the cultivation implement 1 is used through the first cultivation process and the second cultivation process. That is, in the cultivation method of potatoes, potatoes are cultivated in a state where the rhizosphere is limited to the partition region 20 having a depth of 10 to 30 cm and a horizontal cross-sectional area of 60 to 180 cm ² until it is harvested.

[First cultivation process]
The first cultivation step is a step of cultivating potatoes in a low illuminance environment that satisfies a low illuminance condition in which light having an illuminance of 2 k to 10 k [lx] is irradiated for an average of about 12 hours per day. For example, the low light environment is an indoor or outdoor shade. Therefore, in the first cultivation step, for example, a large amount of potato seedlings can be grown in a low-light environment with poor sunlight such that a plurality of the cultivation devices 1 are arranged in multiple stages by effectively utilizing a vertical space.

The period during which the first cultivation process is performed is a period in which roots, stems, and leaves grow with low-intensity light, for example, a period until the number of potato leaves reaches about 20 to 50.
More specifically, in the period of the first cultivation step, when the average temperature of the cultivation environment is T [° C.], the range of 3 to 6 weeks is multiplied by the temperature coefficient C calculated by the following equation (1). Within the first range.
C = 1.65-0.027 × T (1)
The first range is determined to be 3 to 6 weeks when the average temperature T is 24 ° C. In addition, if the same result is obtained, you may calculate the said 1st range according to the said average temperature T on the basis of the other said average temperature T.

  For example, when the average temperature T is 28 ° C., the first range is 2.7 to 5.4 weeks. When the average temperature T is 20 ° C., the first range is 3.3 to 6.7 weeks. Furthermore, when the average temperature T is 6 ° C., the first range is 4.5 to 8.9 weeks.

Here, the temperature coefficient C is determined according to the relationship between the average temperature and the cultivation period shown in Table 1 below.

Specifically, Table 1 above shows the periods of the first cultivation process and the second cultivation process in which the same amount of harvest was obtained under different conditions of the average temperature. For example, Table 1 shows that the average temperature is 23.0 ° C., the first cultivation process is 6 weeks, and the second cultivation process is 6 weeks, and the potato yield is 18. It is 8 degreeC, It has shown that the harvest amount of the potato in the case where the said 1st cultivation process is 7 weeks and the said 2nd cultivation process is 7 weeks was the same.

[Second cultivation process]
In the second cultivation step, the potato after the first cultivation step is cultivated in a high illuminance environment that satisfies a high illuminance condition in which sunlight (illuminance of about 40 k to 100 k [lx]) is irradiated for an average of about 12 hours per day. It is a process. For example, the high illumination environment is sunny outdoors. The high illuminance environment may be an environment in which light having an illuminance of 40 k to 100 k [lx] is irradiated by artificial lighting.

  The period during which the second cultivation process is performed is a period in which the potato grows after the number of leaves has increased to about 20 to 50 in the first cultivation process. Therefore, sufficient photosynthesis is performed by the leaves. Is called. At this time, since the root area of the potato is limited by the partition region 20 of the cultivation device 1, the growth of the root of the potato is saturated in a narrower range than usual, and then the growth of the small potato of the potato starts. Is done. Therefore, according to the cultivation method of the persimmon, the growth of the root of potato can be restricted and the growth of the small persimmon can be started at an early stage, and the persimmon can be harvested in a short period of time.

More specifically, the period of the second cultivation step is within a second range obtained by multiplying the range of 5 to 8 weeks by the temperature coefficient C. The second range is defined to be 5 to 8 weeks when the average temperature T is 24 ° C. If the same result is obtained, the second range may be calculated according to the average temperature T based on the other average temperature T.
For example, when the average temperature T is 28 ° C., the second range is 4.5 to 7.2 weeks. When the average temperature T is 20, the second range is 5.6 to 8.9 weeks. Furthermore, when the average temperature T is 6 ° C., the second range is 7.4 to 11.9 weeks.

  As described above, if cultivating potato with the root zone restricted to the partition region 20 using the cultivating device 1, the growth of potato roots is saturated at an early stage and the growth of small potatoes starts. Potato can be cultivated in a short period of time, and the annual production of potato can be increased compared with the conventional one.

  Here, FIG. 2 shows a potato cultivated in the partition region 20 of the cultivation implement 1 by the cultivation method of cocoons according to the present invention (left side of FIG. 2, referred to as an implementation product) and a general potato (of FIG. 2). Right side, conventional product). As shown in FIG. 2, the embodiment product is a relatively small potato having an outer diameter of about 2 cm to 5 cm, and is about 1/5 to half the size of the conventional product.

Moreover, FIG. 3 shows the potato grown in the division area 20 of the cultivation instrument 1 by the cultivation method of straw according to the present invention (the upper side in FIG. 3, referred to as an implementation product), and the size of the division area 20 is deep. It shows a potato cultivated when it has an area of 40 cm and a horizontal cross section of 80 cm ² (the lower side in FIG. 3, referred to as a comparative product). As shown in FIG. 3, in the above-mentioned product, potato small potatoes grow early because the growth of potato roots is restricted by the partition region 20 during the cultivation period of the first range and the second range. did. On the other hand, in the comparative product, since the root growth of potato was not restricted in the partition area 20 during the cultivation period of the first range and the second range, the roots grew too much and the small pods grew sufficiently. There wasn't. Thus, a clear difference was observed in the growth rate of the gavel between the practical product and the comparative product.

Moreover, according to the cultivation method of the said persimmon, by performing the said 1st cultivation process which uses indoor or an outdoor shade, the period of the said 2nd cultivation process which uses an outdoor sun can be shortened, and the outdoors The annual production per unit area of the farm can be increased. In other words, mass production of potatoes can be realized with a small field.
In particular, by setting the period of the first cultivation step within the first range, it is possible to grow potatoes appropriately until the leaves grow to about 20 to 50 in the first cultivation step. On the other hand, if the period of the first cultivation process is shorter than the first range, the potato leaves are not sufficiently grown, and the period of the second cultivation process becomes unnecessarily long. On the other hand, if the period of the first cultivation step is longer than the first range, the growth rate of potato roots, stems, and leaves is lowered after a certain period of time, so that the production efficiency of straw is lowered.
In addition, by setting the period of the second cultivation step within the second range, it is possible to obtain a high effect in a balanced manner with respect to the amount of potato harvested and the potato production rate. On the other hand, if the period of the second cultivation step is shorter than the second range, the potato small pods are not sufficiently grown and the yield is reduced. On the other hand, if the period of the second cultivation step is longer than the second range, the growth rate of potato small pods decreases after a certain period of time, so that the production efficiency of cocoons decreases.

By the way, the potato cultivated by the method for cultivating the cocoon can be used not only for food but also as fuel for thermal power generation. Specifically, it is possible to produce fuel (biomass solid fuel) by drying potato roots, stems, leaves, or small pods cultivated by the method for cultivation of straw according to the present invention. Here, FIG. 4 (A) shows a fuel obtained by drying and finely cutting small potato small potatoes cultivated by the method for cultivation of cocoons according to the present invention. Since the fuel produced in this way is made from potatoes that can be mass-produced by the straw cultivation method according to the present invention, a sufficient amount can be produced annually, and it is sufficiently effective instead of fossil fuels. Can be used.
In addition, a biomass liquid fuel (such as bioethanol) manufactured from potato cultivated by the cultivating method of the straw is also an example of the present invention. Note that the biomass liquid fuel may be manufactured by a method similar to, for example, well-known biomass ethanol using corn as a raw material, and thus the description of the manufacturing method is omitted here.

[Gansu cultivation equipment 2]
The cultivation device 2 according to the present embodiment is configured in the same manner as the cultivation device 2 (see FIG. 1), and the size of the partition region 20 is a rectangle having a horizontal cross section of 8 cm long × 10 cm wide and an area of 80 cm ² . (An example of a rectangle), and the only difference is that the depth is 45 cm. Thereby, the root zone of the sweet potato grown with the said cultivation device 2 is restrict | limited by the said division area | region 20 whose depth is 45 cm and the area of a horizontal cross section is 80 cm < ² >. On the other hand, it is generally known that sweet potato roots spread to about 0.3 to 1 m ³ . Therefore, when cultivating sweet potato using the cultivation device 2, the growth of the root of the sweet potato is limited in the partition region and is saturated in a narrower range than usual, and the growth of small potatoes of sweet potato begins at an early stage. become.

Here, the size of each partition region 20 is merely an example. Specifically, each of the partition regions 20 may have a depth of 20 to 45 cm and a horizontal sectional area of 80 to 200 cm ² . Moreover, the said cultivation implement 2 may be an individual cultivation implement which has only one said division area 20. Further, the shape of the horizontal section of each of the partition regions 20 is not limited to a rectangle, but may be a circle, an ellipse, a triangle, a square, a hexagon, or other polygons. However, if the horizontal cross section of the partition region 20 is rectangular, the partition regions 20 can be arranged densely in a limited area without providing a useless space. The root zone can be secured as much as possible.

[Growing method of sweet potato]
Hereinafter, the cultivation method of the koji for cultivating sweet potato is demonstrated. The cultivation method of the persimmon includes a third cultivation process for cultivating sweet potato in a low illumination environment that satisfies a predetermined low illumination condition, and a high condition that satisfies a predetermined high illumination condition for the sweet potato after the third cultivation process. It is a two-stage cultivation method which has the 4th cultivation process grown in an illumination environment. In the cultivation method of the persimmon, the cultivation implement 2 is used through the third cultivation step and the fourth cultivation step. That is, in the cultivation method of the koji, the sweet potato is cultivated in a state where the rhizosphere is limited to the partition region 20 having a depth of 20 to 45 cm and a horizontal section area of 80 to ²⁰⁰ cm ² until it is harvested.

[Third cultivation process]
The third cultivation step is a step of cultivating sweet potato in a low illuminance environment that satisfies a low illuminance condition in which light having an illuminance of 2 k to 10 k [lx] is irradiated for an average of about 12 hours per day. For example, the low light environment is an indoor or outdoor shade. Therefore, in the third cultivation step, for example, a large amount of sweet potato seedlings can be grown in a low-light environment with poor sunlight such that a plurality of the cultivation devices 2 are arranged in multiple stages by effectively utilizing a vertical space.

The period during which the third cultivation step is performed is a period in which roots, stems, and leaves grow with light of low illuminance. For example, the period until the number of sweet potato leaves reaches about 20 to 50.
More specifically, in the period of the third cultivation step, when the average temperature of the cultivation environment is T [° C.], the range of 4 to 8 weeks is multiplied by the temperature coefficient C calculated by the following equation (2). Within the third range.
C = 1.65-0.027 × T (2)
The third range is set to be 4 to 8 weeks when the average temperature T is 24 ° C. In addition, if the same result is obtained, you may calculate the said 3rd range according to the said average temperature T on the basis of the other said average temperature T.

  For example, when the average temperature T is 28 ° C., the third range is 3.6 to 7.2 weeks. Further, when the average temperature T is 20 ° C., the third range is 4.4 to 8.9 weeks. Further, when the average temperature T is 6 ° C., the third range is 6.0 to 11.9 weeks.

Here, the temperature coefficient C is determined according to the relationship between the average temperature and the cultivation period shown in Table 2 below.

Specifically, the above Table 2 shows the periods of the third cultivation process and the fourth cultivation process in which the same amount of harvest was obtained under different conditions of the average temperature. For example, Table 2 shows that the average temperature is 23.0 ° C., the third cultivation process is 8 weeks, and the fourth cultivation process is 8 weeks. It is 8 degreeC, It has shown that the harvest amount of the sweet potato in the case where the said 3rd cultivation process is 9.5 weeks and the said 4th cultivation process is 9.5 weeks was the same.

[Fourth cultivation process]
In the fourth cultivation step, the sweet potato after the third cultivation step is cultivated in a high illuminance environment that satisfies a high illuminance condition in which sunlight (illuminance of about 40 k to 100 k [lx]) is irradiated for an average of about 12 hours per day. It is a process. For example, the high illumination environment is sunny outdoors. The high-illuminance environment may be an environment in which light having an illuminance of 40 k to 100 k [lx] is irradiated by artificial lighting.
The period during which the fourth cultivation process is performed is a period during which the sweet potato grows after the number of leaves has increased to about 20 to 50 in the third cultivation process, so that sufficient photosynthesis is performed by the leaves. Is called. At this time, since the sweet potato root zone is limited by the partition region 20 of the cultivation device 2, the growth of the sweet potato root is saturated in a narrower range than usual, and thereafter the growth of the sweet potato small pods starts. Is done. Therefore, according to the cultivation method of the persimmon, the growth of the sweet potato root can be restricted and the growth of the small persimmon can be started at an early stage, and the persimmon can be harvested in a short period of time.

More specifically, the period of the fourth cultivation step is within a fourth range obtained by multiplying the range of 6 to 10 weeks by the temperature coefficient C. The third range is defined to be 6 to 10 weeks when the average temperature T is 24 ° C. In addition, if the same result is obtained, you may calculate the said 3rd range according to the said average temperature T on the basis of the other said average temperature T.
For example, when the average temperature T is 28 ° C., the fourth range is 5.4 to 8.9 weeks. When the average temperature T is 20, the fourth range is 6.7 to 11.1 weeks. Furthermore, when the average temperature T is 6 ° C., the fourth range is 8.9 to 14.9 weeks or less.

  As described above, if cultivating sweet potato with the root zone restricted to the partition region 20 using the cultivation tool 2, the growth of the sweet potato root is saturated at an early stage and the growth of small pods starts. The sweet potato can be cultivated in a short period of time, and the annual production of sweet potato can be increased compared to the conventional one.

Moreover, according to the cultivation method of the said persimmon, by performing the said 3rd cultivation process which uses indoor or an outdoor shade, the period of the said 4th cultivation process which uses an outdoor sun can be shortened, and the outdoors The annual production per unit area of the farm can be increased. In other words, the sweet potato mass production can be realized by a small field.
In particular, by setting the period of the third cultivation step within the third range, the sweet potato can be appropriately grown until the leaf grows to about 20 to 50 in the third cultivation step. On the other hand, if the period of the third cultivation step is shorter than the third range, the sweet potato leaves are not sufficiently grown, and the period of the fourth cultivation step becomes uselessly long. On the other hand, if the period of the third cultivation step is longer than the third range, the growth rate of sweet potato roots, stems, and leaves is lowered after a certain period of time, so that the production efficiency of koji is lowered.
Moreover, by setting the period of the fourth cultivation step within the fourth range, it is possible to obtain a high effect in a well-balanced manner regarding the yield of sweet potato and the production speed of sweet potato. On the other hand, if the period of the fourth cultivation step is shorter than the fourth range, the sweet potato pods are not sufficiently grown and the yield is reduced. On the other hand, if the period of the fourth cultivation step is longer than the fourth range, the growth rate of sweet potato pods decreases after a certain period of time, so that the production efficiency of cocoons decreases.

By the way, the sweet potato cultivated by the cultivation method of the persimmon can be used not only for food but also as fuel for thermal power generation. Specifically, it is possible to produce fuel (biomass solid fuel) by drying sweet potato roots, stems, leaves, or small pods cultivated by the koji cultivation method according to the present invention. Here, FIG. 4 (B) shows a fuel obtained by drying and finely cutting a small sweet potato cultivated by the method for cultivating cocoons according to the present invention. Since the fuel produced in this way is made from sweet potato that can be mass-produced by the koji cultivation method according to the present invention, a sufficient amount can be produced annually, and it is sufficiently effective instead of fossil fuel. Can be used.
In addition, a biomass liquid fuel (such as bioethanol) manufactured from sweet potato cultivated by the koji cultivation method is an example of the present invention. Note that the biomass liquid fuel may be manufactured by a method similar to, for example, well-known biomass ethanol using corn as a raw material, and thus the description of the manufacturing method is omitted here.

[Cultivation result of potato]
In the present Example 1, the cultivation result of the potato using the cultivation method of the straw based on this invention is demonstrated. The potato variety used here is Baron. Here, the following Table 3 shows that when the average temperature T is 24 ° C., the first cultivation process is 5 weeks, and the second cultivation process is 6 weeks using the cultivation tool 1, the partition region 20 The cultivation result when changing the depth of each and the area of a horizontal cross section is shown.

As shown in Table 3 above, in Comparative Examples 11 to 18 where the soil volume (i.e., rhizosphere) in the cultivation device 1 is outside the range of depth 10 to 30 cm and area 60 to 180 cm ² , the harvest per unit area The amount [kg / m ² ] is less than 10 [kg / m ² ]. In Comparative Examples 11 to 18, the production rate in the second range is less than 1.8 [kg / m ² / week], and the production rate over the entire period is 1.0 [kg / m ² / week. Week].

In contrast, as shown in Table 3, the soil volume in culture instrument 1 (i.e., rhizosphere) depth 10 to 30 cm, in Examples 11 to 16 satisfy the range of the area 60～180Cm ^2, units The yield [kg / m ² ] per area is 10 [kg / m ² ] or more. Moreover, in the said Example 11- Example 16, the production rate of the said 2nd range is 1.8 [kg / m < ² > / week] or more, and the production rate of whole period is 1.0 [kg / m < ² > / week>. Week] or more. Therefore, according to the cultivation method of straw according to the present invention, it is possible to obtain a high effect with respect to all of the yield per unit area of potato, the production rate in the second range, and the production rate over the entire period. The depth of the partition region 20 and the area of the horizontal cross section are ranges defined so that the yield [kg / m ² ] per unit area is 10 [kg / m ² ] or more.

Furthermore, in the cultivation method of straw according to the present invention, since the second range using an outdoor field may be about 3 to 6 weeks, potato cultivation may be repeated at least 6 times a year using the same field. it can. In particular, in the cultivation method of straw according to the present invention, since the first cultivation step is performed in the low illumination environment, it is possible to cultivate potato seedlings by stacking the cultivation devices 1 in multiple stages in the vertical direction. The area of land used in the first cultivation process can be significantly reduced.
Specifically, when the size of the partition region 20 in Example 13 is 20 cm deep and the horizontal cross-sectional area is 60 cm ² , the yield per unit area is 15.8 [kg / m ² ]. Here, when the cultivation device 1 is stacked in five stages in the vertical direction and the cultivation method for the persimmon is executed, the yield per 1 m ² of land becomes 79 [kg / m ² ]. And if the cultivation method of the said persimmon is repeated 6 times a year, the sum total will be 474 [kg / m < ² >]. The production amount of this cocoon corresponds to a production amount of about several tens to 100 times that of the conventional case.

[Cultivation result of potato]
In the present Example 2, the cultivation result of the potato using the cultivation method of the cocoon concerning this invention is demonstrated. The potato variety used here is Baron. Here, the following Table 4 shows that when the average temperature T is 24 ° C., the depth of the partition region 20 is 20 cm, and the area of the horizontal section is 80 cm ² , the first cultivation is performed using the cultivation tool 1. The cultivation result when changing the period which performs a process and the said 2nd cultivation process is shown, respectively.

As shown in Table 4 above, in Comparative Examples 21 to 28 where at least one of the periods of the first cultivation process or the second cultivation process deviates from the first range or the second range, the production rate of the entire period is It is less than 1.0 [kg / m ² / week].

On the other hand, as shown in the said Table 4, in Example 21-Example 26 in which the period of the said 1st cultivation process and the said 2nd cultivation process each satisfy | fills the said 1st range and the 2nd range, production of all the periods It can be seen that the rate is 1.0 [kg / m ² / week] or more, and the production efficiency is higher than those of Comparative Examples 21 to 28. That is, the first range and the second range are ranges defined so that the production rate of the whole period is 1.0 [kg / m ² / week] or more.

[Cultivation result of sweet potato]
In Example 3, the cultivation results of sweet potato using the koji cultivation method according to the present invention will be described. The sweet potato variety used here is red azuma. Here, the following Table 5 shows that when the average temperature T is 24 ° C., the third cultivation process is 6 weeks, and the fourth cultivation process is 8 weeks, using the cultivation tool 2, the partition region 20 The cultivation result when changing the depth of each and the area of a horizontal cross section is shown.

As shown in Table 5, the cultivation instrument soil volume in 2 (i.e., rhizosphere) depth 20～45Cm, Comparative Examples 31 to Comparative Example 38 outside the range of the area 80～200Cm ^2, per unit area harvested The amount [kg / m ² ] is less than 17.0 [kg / m ² ]. In Comparative Examples 31 to 38, the production rate in the fourth range is less than 2.2 [kg / m ² / week], and the production rate for the entire period is 1.3 [kg / m ² / week]. Week].

On the other hand, as shown in the said Table 5, in Example 31- Example 36 in which the soil volume (namely, rhizosphere) in the said cultivation implement 2 satisfy | fills the range of depth 20-45 cm and area 80-200 cm < ² >, a unit The yield [kg / m ² ] per area is 17 [kg / m ² ] or more. Further, in the Examples 11 to 16, and the production rate of the fourth range 2.2 [kg / ^{m 2} / week] or more, the production rate of the whole period is 1.3 [kg ^{/ m} 2 ^/ Week] or more. Therefore, according to the cultivation method of koji according to the present invention, a high effect can be obtained with respect to all of the yield per unit area of sweet potato, the production rate in the fourth range, and the production rate over the entire period. The depth of the partition region 20 and the area of the horizontal cross section are ranges defined so that the yield [kg / m ² ] per unit area is 17 [kg / m ² ] or more.

Furthermore, in the cultivation method of koji according to the present invention, since the fourth range using an outdoor field may be about 6 to 10 weeks, the sweet potato cultivation may be repeated at least four times a year using the same field. it can. In particular, in the cultivation method of persimmon according to the present invention, since the third cultivation step is performed in the low-light environment, it is possible to cultivate sweet potato seedlings by stacking the cultivation equipment 2 in multiple stages in the vertical direction. The area of land used in the third cultivation process can be significantly reduced.
Specifically, when the size of the partition region 20 in Example 35 is 45 cm deep and the area of the horizontal cross section is 80 cm ² , the yield per unit area is 19.5 [kg / m ² ]. Here, when the cultivation device 2 is stacked in five stages in the vertical direction and the cultivation method of the persimmon is executed, the yield per 1 m ² of land is 97.5 [kg / m ² ]. And if the cultivation method of the said persimmon is repeated 4 times a year, the sum total will be 390 [kg / m < ² >]. The production amount of this cocoon corresponds to a production amount of about several tens to 100 times that of the conventional case.

[Cultivation result of sweet potato]
In the present Example 4, the cultivation result of sweet potato using the koji cultivation method according to the present invention will be described. The sweet potato variety used here is red azuma. Here, Table 6 below uses the cultivation tool 2 and the third cultivation when the average temperature T is 24 ° C., the depth of the partition region 20 is 30 cm, and the area of the horizontal section is 80 cm ^2. The cultivation result when changing the period which performs a process and the said 4th cultivation process is shown, respectively.

As shown in Table 6 above, in Comparative Examples 41 to 48 where at least one of the periods of the third cultivation process or the fourth cultivation process deviates from the third range or the fourth range, the production rate of the entire period is Less than 1.3 [kg / m ² / week].

On the other hand, as shown in Table 6 above, in Examples 41 to 46 in which the periods of the third cultivation process and the fourth cultivation process satisfy the third range and the fourth range, respectively, the production for the entire period It can be seen that the rate is 1.3 [kg / m ² / week] or more, and the production efficiency is higher than those of Comparative Examples 41 to 48. That is, the third range and the fourth range are ranges defined so that the production rate of the entire period is 1.3 [kg / m ² / week] or more.

1: Cultivation cultivation equipment 2: Cultivation cultivation equipment 11: Storage unit 12: Vertical partition wall 13: Horizontal partition wall 14: Bottom surface 20: Partition area

Claims (18)

A cultivation method of potato characterized in that the root zone is limited to a partitioned region having a depth of 10 to 30 cm and a horizontal cross-sectional area of 60 to 180 cm ² to grow potatoes.   A first cultivation process for cultivating the potato in a low illuminance environment that satisfies a predetermined low illuminance condition, and a first cultivating the potato after the first cultivation process in a high illuminance environment that satisfies a predetermined high illuminance condition. The cultivation method of the straw of Claim 1 which has a 2 cultivation process.   The said low illumination intensity condition is receiving the light of illumination intensity 2k-10k [lx], and the said high illumination intensity condition is receiving the light or sunlight of illumination intensity 40k-100k [lx]. Cultivation method.   The cultivation method for strawberries according to claim 2 or 3, wherein the low illumination environment is an indoor or outdoor shade, and the high illumination environment is an outdoor sun. The period of the first cultivation step is within the first range obtained by multiplying the range of 3 to 6 weeks by the temperature coefficient C calculated by the following equation (1), when the average temperature of the cultivation environment is T [° C.]. The cultivation method of persimmons in any one of Claims 2-4.
C = 1.65-0.027 × T (1)   The cultivation method for strawberries according to claim 5, wherein the period of the second cultivation step is within a second range obtained by multiplying the range of 5 to 8 weeks by the temperature coefficient C. A method for cultivating sweet potato, characterized in that the sweet potato is cultivated by restricting the rhizosphere to a partitioned region having a depth of 20 to 45 cm and a horizontal cross section of 80 to 200 cm ² .   A third cultivation step of cultivating the sweet potato in a low illuminance environment that satisfies a predetermined low illuminance condition, and a first cultivating the sweet potato after the third cultivation step in a high illuminance environment that satisfies a predetermined high illuminance condition The cultivation method of the straw of Claim 7 which has 4 cultivation processes.   9. The firewood according to claim 8, wherein the low illuminance condition is to receive light having an illuminance of 2 k to 10 k [lx], and the high illuminance condition is to receive light having an illuminance of 40 k to 100 k [lx] or sunlight. Cultivation method.   The cultivation method for strawberries according to claim 8 or 9, wherein the low illumination environment is an indoor or outdoor shade, and the high illumination environment is an outdoor sun. The period of the third cultivation step is within a third range obtained by multiplying the range of 4 to 8 weeks by the temperature coefficient C calculated by the following equation (2) when the average temperature of the cultivation environment is T [° C.]. The cultivation method of persimmons in any one of Claims 7-10.
C = 1.65-0.027 × T (2)   The period of the said 4th cultivation process is in the 4th range which multiplied the said temperature coefficient C in the range of 6 to 10 weeks, The cultivation method of the cocoon of Claim 11.   The cultivation method of the cocoon in any one of Claims 1-12 which cultivate several potatoes or sweet potatoes using the cultivation tool of the cocoon which has the said several division area partitioned off by the partition.   A fuel using cocoons produced from potato or sweet potato roots, stems, leaves, or small pods cultivated by the cultivation method of cocoons according to any one of claims 1 to 13. A cultivation device for grapes comprising an accommodation part for restricting the root zone of potato to a partitioned region having a depth of 10 to 30 cm and a horizontal cross section of 60 to 180 cm ² . A cultivation device for grapes characterized by comprising an accommodation part for restricting the root zone of sweet potato to a partition region having a depth of 20 to 45 cm and a horizontal cross section of 80 to 200 cm ² .   The said accommodation part has the said some division area partitioned off by the partition, The cultivation tool of the straw of Claim 15 or 16   The cultivation device for strawberries according to claim 17, wherein a bottom surface of the housing portion is provided so as to be openable and closable.