JP6828210B1 - Vegetation method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To construct a seedling on a slope without requiring complicated construction, the construction itself is inexpensive, and the roots supporting the seedlings bite into the soil of the slope well, and the rooting is good. Providing a vegetation method that improves. SOLUTION: This is a vegetation method A in which a seedling is used as a specially grown seedling P on a slope, and a coating step S1 for covering the slope with a non-woven fabric sheet, a non-woven fabric sheet fixing step S2 for fixing the non-woven fabric sheet to the slope, A planting port forming step S3 for forming a planting port for vegetation on a non-woven fabric sheet, a planting hole forming step S4 for making a planting hole for planting a specially grown seedling P on a slope directly below the planting port, and for planting. It comprises a planting step S5 in which a specially grown seedling P is planted in a hole through a planting port. [Selection diagram] Fig. 1

Description

The present invention relates to a vegetation method such as a slope, and more specifically, it does not require complicated slope construction and is inexpensive, and the roots supporting the seedlings bite into the soil of the slope well, and the rooting becomes good and the slope becomes good. Regarding the vegetation method that improves the retention rate.

If the slopes (so-called slopes) of the land, reclaimed land, river embankments, mountains, roads, etc. after construction are left exposed, they will be eroded, peeled off, depressed, etc. It is easy to be in a state.
Furthermore, due to devastation, earth and sand may flow out due to a large amount of wind and rain, which is dangerous.
It also looks bad.
For this reason, it is widely practiced to apply vegetation to slopes that have been or may be devastated.

As a method of this vegetation, for example, there is a vegetation method as in Patent Document 1. This includes a first covering step for covering the slope with a first non-woven fabric sheet, a soil dressing layer forming step for forming a soil dressing layer on the first non-woven fabric sheet, and a second non-woven fabric sheet covering the soil dressing layer. The second covering step, the non-woven fabric sheet fixing step of fixing the first non-woven fabric sheet to the slope together with the second non-woven fabric sheet, the plant opening forming step of forming a plant for vegetation on the second non-woven sheet, right under the plant. It is a vegetation method characterized by consisting of a hole forming step for planting in which a hole for planting is made in the soil dressing layer and a planting step in which a vegetation material is planted together with soil in the hole for planting.

In the vegetation method of Patent Document 1, the type of seedling or the method of raising seedlings is not disclosed. In order to establish vegetation that prevents the devastation of the slope, it is necessary that the branches and root masses of the seedlings used for planting are in a form suitable for planting.
Specifically, if the branch branches overhanging in the lateral direction grow too much, it hinders the work of dividing the seedlings into individual plants, and the workability is reduced. Furthermore, if the supporting roots that project laterally are developed during vegetation on the slope, the supporting roots are easily damaged. If the supporting roots are damaged, the growth is hindered, and worse, it causes root rot.
Then, the support roots do not bite into the slope poorly, and the seedlings do not grow on the slope, or worse, die, and the retention rate decreases.

Further, as a method for growing seedlings used for vegetation, for example, there is a growing device and method of Patent Document 2 or a seedling raising method using a seedling raising material of Patent Document 3.
The growth apparatus of Patent Document 2 includes a band-shaped cultivation bed in which a zigzag fold is formed, a folding angle control member, a support member, a light source, and a nutrient supply unit.
Further, the seedling raising material of Patent Document 3 contains cellulose acylate, and in the seedling raising method using this, the nursery is placed inside the temperature / humidity controller to raise seedlings.

In the seedling raising device of Patent Document 2 or the seedling raising method using the seedling raising material of Patent Document 3, a growing device or a temperature / humidity controller is required.
That is, seedlings are industrially produced, require dedicated equipment and energy to operate the equipment, and require labor for management.
Furthermore, even in these documents, there is no suggestion about the morphology of branches and root masses, and the idea of growing seedlings in a morphology suitable for vegetation on slopes is not disclosed.

Japanese Patent No. 569291 Japanese Unexamined Patent Publication No. 2014-60938 JP-A-2019-41587

The present invention has been developed in response to the above-mentioned problems.
That is, the present invention does not require the construction of a complicated slope, the construction itself is inexpensive, the roots are not easily damaged during planting, the roots supporting the seedlings bite into the soil on the slope well, and the rooting is good. As a result, it is an object of the present invention to provide a vegetation method in which the colonization rate of seedlings on the slope is improved.

As a result of diligent studies, the present inventor has found that the use of specially grown seedlings improves the biting of the supporting roots of the seedlings into the soil on the slope. The present invention is based on this finding.

The present invention is (1) a vegetation method in which germinated seedlings are used as specially grown seedlings on a slope, a coating step of covering the slope with a non-woven sheet, a non-woven sheet fixing step of fixing the non-woven sheet to the slope, and a non-woven fabric. A planting port forming step of forming a planting port for vegetation on a sheet, a planting hole forming process of making a planting hole for planting a specially grown seedling on a slope directly below the planting port, and a planting hole in the planting hole. The specially raised seedlings are the seedlings that are grown from the seeds that have been left in the water and sunk through the special seedling raising process. , Form a foundation soil layer with vermiculite in an open container, sow seeds at a distance of 1 to 3 cm without contacting each other on the foundation soil layer, cover the seeds with vermiculite, and cover 1-2 cm. A filling layer is formed so as to be thick, and the open container is left outdoors in the half shade to germinate seeds and grow them into specially grown seedlings of a certain size. The specially grown seedlings in the planting process are grown from the main roots. A shape in which the development of supporting roots, which are roots extending in the lateral direction, is suppressed and the main root itself grows efficiently, and the main branch in the vertical direction grows, and the growth of branch branches in the lateral direction is suppressed. It exists in the vegetation method .
Here, the bud seedling refers to a seedling in a germinated state, that is, a seedling of a plant in which buds, stems (stems), leaves and roots have developed.

The present invention exists in the vegetation method described in (1) above, wherein the specially grown seedling has a shape in which the lower end of the taproot is sharp .

The vegetation method of the present invention is a vegetation method in which bud seedlings are used as specially grown seedlings on a slope, and includes a coating step of covering the slope with a non-woven fabric sheet, a non-woven fabric sheet fixing step of fixing the non-woven fabric sheet to the slope, and a non-woven fabric. A planting port forming step of forming a planting port for vegetation on a sheet, a planting hole forming process of making a planting hole for planting a specially grown seedling on a slope directly below the planting port, and a planting hole in the planting hole. By having a planting process of planting specially grown seedlings through the non-woven fabric, complicated slope construction is not required and the number of construction steps is small.
Therefore, the construction period is shortened and the cost is low.
Further, even if a large amount of rainwater is used, rainwater can be actively flowed along the non-woven fabric sheet, so that it is possible to prevent erosion of the slope due to sudden rainwater.
Furthermore, while the taproots that extend vertically downward develop in the specially grown seedlings, the growth of the supporting roots that extend substantially in the lateral direction is suppressed as much as possible, so that the roots of adjacent seedlings do not become entangled with each other, and the work of dividing the stocks. Improves sex. Further, the roots are not easily damaged during planting, the supporting roots bite into the slope of the specially cultivated seedlings well, and the rooting is good, so that the retention rate of the specially cultivated seedlings can be improved.

In the vegetation method of the present invention, since the specially cultivated seedlings are seedling buds grown from seeds through a special seedling raising process, the slopes of the specially cultivated seedlings are well established and the slopes are efficiently degraded. It becomes possible to prevent.

In the vegetation method of the present invention, in the special seedling raising process, the seeds are left in water and sunk, so that the seed germination rate is high and the specially grown seedlings are efficiently grown. Is possible.

In the vegetation method of the present invention, in the special seedling raising step, (a) a foundation soil layer is formed in an open container by vermiculite, (b) seeds are sown in the foundation soil layer without contacting each other, and (c) on the seeds. Is covered with vermiculite to form an embankment layer to a certain thickness, and (d) the open container is left outdoors in the half shade to germinate seeds and grow them into specially grown seedlings of a certain size. As a result, the growth of seedlings can be easily controlled, and seedlings with an optimum degree of growth can be obtained during construction on a slope. This makes it possible to deal with cases where the construction time on the slope is unexpectedly changed.
Further, since the special seedling raising process is performed outdoors in the half shade, it is possible to reduce the man-hours and costs for managing the seedlings without requiring special equipment, energy such as electric power, and the like.
In addition, it becomes possible to grow specially grown seedlings suitable for vegetation. More specifically, in the special seedling raising process, the taproots in which the specially raised seedlings grow in the substantially vertical direction develop, while the growth of the supporting roots in which the specially raised seedlings grow in the substantially lateral direction is suppressed. As a result, the supporting roots are less likely to be damaged in the planting process.
Even after the planting process, the entangled root mass stabilizes and the rooting becomes good as if it bites into the soil on the slope, and as a result, the retention rate of the specially bred seedlings is improved.
Further, since the vermiculite is put in the open container, the seedlings can be easily moved together with the open container as needed.

In the vegetation method of the present invention, the germination rate of seeds is improved when the thickness of the embankment layer is 1 to 2 cm. This makes it possible to grow specially grown seedlings more efficiently.

In the vegetation method of the present invention, since the length of the taproot of the specially cultivated seedling in the planting process is 20 cm or more, the specially cultivated seedling has the strength to withstand the planting on the slope from the viewpoint of rooting. , The retention rate on the slope is improved. Therefore, it is possible to more effectively prevent the devastation of the slope.

FIG. 1 is a block diagram for explaining the vegetation method. FIG. 2 is a cross-sectional view of a slope showing the vegetation method. FIG. 3A is a diagram showing an example of a notch in the plant opening forming step. FIG. 3B is a diagram showing an example of a notch in the planting opening forming step. FIG. 3C is a diagram showing an example of a notch in the plant opening forming step. FIG. 4 (A) is a view in which the notch of FIG. 3 (A) is opened. FIG. 4 (B) is a view in which the notch of FIG. 3 (B) is opened. FIG. 4 (C) is a view in which the notch of FIG. 3 (C) is opened. FIG. 5 is a perspective view showing an open container. FIG. 6A is a cross-sectional view illustrating an open container in which a foundation soil layer is formed. FIG. 6B is a cross-sectional view illustrating a state in which seeds are sown in the foundation soil layer. FIG. 6C is a cross-sectional view illustrating an open container in which an embankment layer is formed. FIG. 6D is a cross-sectional view illustrating an open container in which seeds have germinated. FIG. 7 is a top view showing a planting opening that has undergone the planting process. FIG. 8 shows the specially raised seedlings obtained in Experiment 1. FIG. 9 is a cross-sectional view of a slope showing the vegetation method according to another embodiment. FIG. 10 is a cross-sectional view of a slope showing a vegetation method according to another embodiment.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings as necessary. In the drawings, the same elements are designated by the same reference numerals, and duplicate description will be omitted.
Further, unless otherwise specified, the positional relationship such as up, down, left, and right shall be based on the positional relationship shown in the drawings. Furthermore, the dimensional ratios in the drawings are not limited to the ratios shown.

The specially grown seedling P used in the vegetation method A of the present invention is a so-called seedling seedling in which seeds are germinated and grown.
As the plant species of the specially raised seedling P, various woody plants such as trees, middle trees, and shrubs are used.
The root system of the specially bred seedling P is mainly composed of a taproot extending vertically downward and a supporting root extending substantially laterally (approximately perpendicular to the main root).

FIG. 1 is a block diagram for explaining the vegetation method A.
The vegetation method A of the present invention is a vegetation method A in which seedlings are used as specially grown seedlings P on slope 2, and a special seedling raising step S6 for growing specially grown seedlings P from seeds and a non-woven sheet 3 on slope 2 are used. Covering step S1 covering with, a non-woven sheet fixing step S2 for fixing the non-woven sheet 3 to the slope 2, a planting port forming step S3 for forming a planting port 31 for vegetation on the non-woven sheet 3, and directly below the planting port 31. A hole forming step S4 for forming a hole 21 for planting a specially cultivated seedling P for planting the specially cultivated seedling P on the slope 2 of the above, and a planting step S5 for implanting the specially cultivated seedling P through the planting port 31 in the planting hole 21. Become.

FIG. 2 is a cross-sectional view of a slope 2 showing the vegetation method A.
In the coating step S1, the non-woven fabric sheet 3 is laid on the slope 2.
The non-woven fabric sheet 3 is made of, for example, a rectangular non-woven fabric having a width of about 2 m and a length of about 50 m.
The non-woven fabric sheet 3 preferably has a water permeability of 1 × 10 ^-3 to ^10-5 (cm / sec).
As a result, even if it rains suddenly, the rainwater is guided to flow downward along the non-woven fabric sheet 3 (along the slope 2), and the discharge is promoted.
On the other hand, by having an appropriate water permeability, rainwater or the like can be absorbed by the soil on the slope 2 under the non-woven fabric sheet 3, and the moisture content of the soil can be maintained.
As a result, the specially grown seedling P planted on the slope 2 can be sufficiently grown as described later.
Further, by laying the non-woven fabric sheet 3, there is an effect of preventing (that is, preventing) the growth of grass buds (that is, weeds) other than the specially grown seedling P that extends upward from the slope 2.

The material of the non-woven fabric sheet 3 is preferably one made of synthetic fibers (polyester, rayon, etc.). It is also possible to use biodegradable fibers.
Since the non-woven fabric sheet 3 is made of synthetic fibers, it has an advantage that it does not easily rot for several years after construction and has good shape retention.
Further, since the non-woven fabric sheet 3 made of these materials has a degree of freedom of stretching, workability is improved in the planting port forming step S3, the planting hole forming step S4, and the planting step S5, which will be described later.
Further, when a fiber having biodegradability is used, the non-woven fabric sheet 3 is naturally decomposed after the specially grown seedling P has sufficiently grown, so that the labor of disposal is not required and the environmental load can be reduced. .. In addition, the decomposed components become nutrients for the specially raised seedling P.

When the non-woven fabric sheet 3 is laid on the slope 2, a certain portion of the end portion of the non-woven fabric sheet 3 is embedded in the soil of the slope 2.
When laying the non-woven fabric sheet 3, if the construction area is larger than the non-woven fabric sheet 3, the construction area is widened by connecting a large number of sheet-like non-woven fabric sheets 3 having a certain size in a plane. At this time, the ends of the plurality of non-woven fabric sheets 3 are in a state where a certain area is overlapped with each other.
In that case, it is preferable that the ends of the non-woven fabric sheet 3 are overlapped and adhered to each other.

In the non-woven fabric sheet fixing step S2, the non-woven fabric sheet 3 may be corroded in a state where the specially grown seedling P has grown to some extent on the slope 2.
In this case, in addition to protecting the soil from rainwater and strong winds by the above-ground parts (branches, leaves, etc.) of the specially grown seedling P, the root system of the specially grown seedling P retains water and physically soil. Is maintained, it is possible to prevent the slope 2 from being devastated even if the non-woven fabric sheet 3 is corroded.

After laying the non-woven fabric sheet 3, the non-woven fabric sheet 3 is fixed to the slope 2 by using a fixing tool 4 such as a fixing pin.
In this case, the stop pin is driven into the soil on the slope 2 from above the non-woven fabric sheet 3. As the stop pin, a nail-shaped pin or a U-shaped pin can be preferably used.
Since the non-woven fabric sheet 3 is exposed to the outside air, it may be rolled up due to wind and rain or the like. This can be prevented by fixing the non-woven fabric sheet 3 to the slope 2 with a stop pin.
When a plurality of non-woven fabric sheets 3 are laid, it is preferable that the stop pins are also driven into the portions where the ends of the non-woven fabric sheets 3 are overlapped with each other.
Further, as described above, the peripheral edges of the non-woven fabric sheet 3 are embedded in the soil at a certain distance. At this time, it is preferable that all the ends of the non-woven fabric sheet 3 outside the stop pin driven to the outermost side are all embedded in the soil. As a result, the non-woven fabric sheet 3 is prevented from being rolled up or floating from the slope 2, and the non-woven fabric sheet 3 can be firmly fixed to the slope 2.

In the planting port forming step S3, a planting port 31 for planting the specially grown seedling P is formed on the non-woven fabric sheet 3 fixed to the slope 2.
3 (A) to 3 (C) are views showing an example of the notch S in the planting opening forming step S3.
FIG. 3A is an example in which a Z-shaped notch S is opened, and FIG. 3B is an example in which a cross-shaped notch S is opened. Further, FIG. 3C is an example in which a V-shaped notch S is opened.
The planting port 31 is composed of a linear notch S formed in the non-woven fabric sheet 3.
Since the planting port 31 is composed of the linear notch S, the work of forming the planting port 31 can be simplified and the work efficiency is improved.
Further, the notch S of the planting port 31 can be formed by using a cutting tool such as scissors or a knife.
The cut end of the notch S is preferably as thin as possible. As a result, as will be described later, the portion of the slope 2 where the soil is exposed can be made as small as possible after the planting formation is completed.

4 (A) to 4 (C) are views in which the cutouts S of FIGS. 3 (A) to 3 (C) are opened.
FIG. 4 (A) is a view in which the Z-shaped notch S of FIG. 3 (A) is opened, and the opened planting port 31 has a rectangular shape.
FIG. 4 (B) is a view in which the cross-shaped notch S of FIG. 3 (B) is opened, and the opened planting port 31 has a diamond shape.
Further, FIG. 4C is a view in which the V-shaped notch S of FIG. 3C is opened, and the opened planting opening 31 has a triangular shape.
As described above, since the shape of the planting port 31 can be changed by the shape of the notch S, it is possible to select an appropriate shape according to the state of the root mass of the specially raised seedling P.
In particular, since the Z-shaped notch S has a notch S formed by a single stroke and a rectangular planting opening 31 is formed, it can be used even when the root mass of the specially raised seedling P is relatively large.
Another advantage is that the construction efficiency is good.
However, regardless of the shape of the notch S, the size and shape of the planting port 31 can be adjusted to some extent by changing the degree of opening.
Further, as described above, since the non-woven fabric sheet 3 is slightly stretched, it is possible to widen the planting port 31 at the time of construction, and after the construction, the notched end is pulled to make the excess planting port 31 as small as possible. be able to.

Next, in the planting hole forming step S4, a hole for planting the specially grown seedling P is dug in the soil on the slope 2 at a position corresponding to the planting port 31 formed in the planting port forming step S3.
The planting hole 21 differs depending on the size of the root mass of the specially grown seedling P, but if the specially grown seedling P is medium, the length of the taproot is 20 cm or more, and the depth of the planting hole 21 also corresponds to this. It will be the depth.
By the way, in this case, the height of the above-ground portion of the specially raised seedling P is also 20 cm or more.
That is, since the specially raised seedling P usually has a root mass, the planting hole 21 may be large enough to accommodate the root mass.
The specific method of drilling the planting hole 21 is to push a transplanting iron (scoop, etc.) into the soil on the slope 2 through the planting port 31 and move it laterally at a certain angle to push the soil away, and this part is created. Is the hole 21 for implantation.
As described above, the planting hole forming step S4 forms a space as a hole for accommodating the root mass of the specially grown seedling P.

Next, in the planting step S5, the specially grown seedling P is planted in the planting hole 21 via the planting port 31.
As for the specially raised seedling P, the seedlings grown in the above-mentioned special seedling raising step S6, which are in a state of being divided into each strain from the opening container 1, are used.
In this case, the specially grown seedling P is grown in a special state using vermiculite in the open container 1 in which the foundation soil layer 11 and the embankment layer 12 are formed.
In the root mass, taproots develop, while laterally extending support roots do not develop much.
As a result, the roots of the specially grown seedlings P adjacent in the lateral direction in the opening container 1 are less entangled, and the stocks can be easily divided.
Also, in the branches, while the main branch develops, the branch branch extending in the lateral direction does not develop so much.
As a result, there is little entanglement of the branches of the adjacent specially raised seedlings P in the opening container 1, the strains can be easily divided, and the workability of the strains is improved.
In the planting step S5, the specially grown seedling P is planted in the planting hole 21 on the slope 2 through the planting port 31 formed on the non-woven fabric sheet 3. When the specially raised seedling P is planted, as described above, the supporting roots extending in the lateral direction as the root mass are not so developed, so that they are less likely to be damaged.
Therefore, the supporting roots bite between the debris and stones contained in the slope, and the rooting becomes good.
As a result, the retention rate of seedlings is improved.
On the other hand, in the specially bred seedling P, since the branch branch extending in the lateral direction is not developed as a branch, it is easy to handle and the workability of planting is good.
In this case, since the planting hole 21 formed in the planting hole forming step S4 and the planting port 31 of the non-woven fabric sheet 3 are located at the corresponding positions, a special case in which the planting hole 21 has a root mass together with soil through the planting port 31. Plant the raised seedling P.
Then, the soil around the plant is pressed and hardened.
Here, after planting the root mass, the non-woven fabric sheet 3 stretches when pulled, so the end of the notch S is pulled to make the planting opening 31 around the stem of the specially grown seedling P as small as possible to expose the soil. It is preferable not to do so.

FIG. 5 is a perspective view showing the opening container 1.
In the special seedling raising step S6, the special seedling raising P is grown from the seeds using the opening container 1.
The opening container 1 is a box-shaped container with an opening at the top, and from the viewpoint of ease of movement and the size of specially raised seedlings, for example, the length and width are about 50 to 65 cm × 20 to 35 cm, and the depth is about 25 to 35 cm. It is preferable that it is.

FIG. 6A is a cross-sectional view illustrating the open container 1 in which the foundation soil layer 11 is formed.
In the special seedling raising step S6, (a) vermiculite is used in the opening container 1 to first form the foundation soil layer 11.
In order to form the foundation soil layer 11, vermiculite is put into the opening container 1 at the 8th minute with respect to the depth of the opening container 1 as a guide, and the surface is leveled flat.
Here, vermiculite is a soil for horticulture in which a bitter melon stone is thermally expanded, and has excellent properties of light weight and water retention, and vermiculite itself does not contain nutrients for plants.
As will be described later, the vermiculite foundation soil layer 11 efficiently promotes the growth of the taproots of the specially bred seedling P, while suppressing the growth of the supporting roots, so that the soil (especially debris) on the slope to be constructed later is used. A specially grown seedling P having a root mass that effectively bites into the seedling is obtained.

By setting the depth of the opening container 1 to about 25 to 35 cm, the roots of the specially grown seedling P can be sufficiently grown to a size suitable for planting on the slope 2.
As a result, after planting on the slope 2 described later, the specially grown seedling P can sufficiently absorb water and nutrients from the soil on the slope 2, and at the same time, the specially grown seedling P is supported on the soil on the slope 2. The roots can bite into it, and the specially raised seedling P can support its own weight.
Further, by setting the overall size of the opening container 1 to be about 50 to 65 cm × 20 to 35 cm in length and width and about 25 to 35 cm in depth, the foundation soil layer 11, the embankment layer 12, and the grown special breeding seedling P can be obtained. Even in the state of being contained, the opening container 1 can be carried and moved relatively easily.
As a result, the opening container 1 can be moved to an appropriate place according to the growth state of the specially raised seedling P and changes in the surrounding conditions.
For the opening container 1, for example, a size can be selected from known planters and used.

FIG. 6B is a cross-sectional view illustrating a state in which seed P1 is sown in the foundation soil layer 11.
After the foundation soil layer 11 is formed, (b) the seeds P1 of the specially grown seedlings P are sown in the foundation soil layer in a state where they do not come into contact with each other.
At this time, the seeds P1 are sown at regular intervals as much as possible.
Here, the distance between the seeds P1 is preferably about 1 to 3 cm.
This makes it possible to grow as many seedlings as possible in a small area.
The foundation soil layer 11 using vermiculite suppresses the growth of supporting roots, which are roots extending laterally from the taproots, as much as possible, and the taproots themselves grow efficiently.
That is, the growth of taproots is promoted more than the growth of supporting roots extending substantially laterally.
Therefore, even if the spacing between the seeds P1 is as described above, the supporting roots are less likely to be entangled with the supporting roots of the adjacent seedlings, and the specially bred seedlings P can be efficiently separated into individual stocks. And workability is improved.

FIG. 6C is a cross-sectional view illustrating the open container 1 in which the embankment layer 12 is formed.
After sowing the seed P1, (c) the seed P1 is covered with vermiculite to form an embankment layer 12 having a constant thickness.
From the viewpoint of germination rate, the embankment layer 12 is preferably about 1 to 2 cm in thickness. At this time, the seed P1 is embedded by the embankment layer 12 while being placed on the surface of the foundation soil layer 11.
By forming such a vermiculite embankment layer 12, it is possible to prevent the seed P1 from drying out, and the germination rate of the seed P1 is improved.
Further, by providing the embankment layer 12, the growth of the main branch in the vertical direction is promoted at the initial stage of germination, and the growth of the branch branch in the lateral direction is suppressed.
Since the branch branches are less likely to be entangled with the branch branches of adjacent seedlings, it is possible to efficiently perform the stock division work for separating the specially raised seedlings P for each stock.

FIG. 6D is a cross-sectional view illustrating the open container 1 in a state where the seed P1 has germinated.
After forming the embankment layer 12, (d) the open container 1 is left outdoors in the half shade, and the seed P1 is germinated to grow into a specially grown seedling P having a certain size.
Here, the half-shade refers to an environment in which a shading rate of about 1/3 to 1/2, which is not exposed to direct sunlight, and a constant amount of light is maintained.
For example, a place where sunlight through the trees points throughout the day is preferably used. It does not matter that the sunlight is pointing for several hours a day.
The place where the opening container 1 is installed is preferably a place where the soil is exposed. By installing the opening container 1 in a place where the soil is exposed, the temperature and humidity are maintained in a state suitable for growing the specially grown seedling P.
Further, if there is a water place such as a river or a pond in the vicinity, the humidity is particularly maintained, so that the specially grown seedling P can be appropriately grown.

After leaving the open container 1 outdoors in the half shade, the specially grown seedling P is grown until the length of the taproot is about 25 cm to 35 cm. Usually, it takes about 12 months. During this period, the specially cultivated seedling P is not watered or treated with cheesecloth to protect it from the cold, except in situations where extremely bad weather continues.
By growing the specially cultivated seedling P until the length of the taproot is about 25 cm to 35 cm, the rooting of the specially cultivated seedling P on the slope 2 becomes good, and the strength becomes strong enough to withstand planting.
By leaving the open container 1 outdoors in the half-shade to grow the specially grown seedling P, no special equipment, energy, etc. for growing the specially grown seedling P is required, and the management man-hours and costs are reduced. It becomes possible.
Further, by setting the depth of the opening container 1 to about 25 cm to 35 cm, the specially grown seedling P does not grow to a certain size or more even if it is left for a longer period of time. As a result, even if the construction on the slope 2 is postponed due to unexpected circumstances, it is possible to prevent the specially grown seedling P from growing too much and becoming unsuitable for construction. ..
By the way, it is preferable that the lower end of the taproot of the specially bred seedling P is in a sharp state. Since the lower end of the taproot is sharp, it is possible to fall asleep better when it is later planted on the slope 2.

After growing the specially raised seedling P through the special seedling raising step S6, vegetation on the slope 2 is performed this time in the planting step S5.
The vegetation method A of the present invention can be applied to the portion to be constructed (slope 2) as long as the soil is exposed and vegetation is possible on the slope 2.
If the soil on the slope 2 contains grass roots, it is preferable to remove them in advance as much as possible.
By the way, since the soil debris on the slope 2 is included, unlike the specially bred seedling P of the present invention, when the supporting roots are developed as in the conventional case, the supporting roots are damaged by the debris or the like at the time of planting. Easy to attach.
When the supporting roots are damaged, the ability of the specially bred seedling P to support its own weight is weakened, and the ability to absorb nutrients from the soil is also reduced.
It also inhibits the growth of new roots. Therefore, it becomes a factor that lowers the colonization rate of the specially raised seedling P on the slope.
Here, in this embodiment, as described above, the specially raised seedling P is grown by the special seedling raising step S6, and while the taproot extending vertically downward is developed, the growth of the supporting root extending substantially laterally is developed. Is suppressed. For this reason, the supporting roots are less likely to be damaged during stock splitting and planting.
Therefore, after the specially cultivated seedling P is planted on the slope through the planting step S5, the supporting roots grow efficiently in the lateral direction.
Specifically, the supporting roots entangle and grow between the debris contained in the soil on slope 2. Therefore, the root mass is stable and the rooting is good, and as a result, the colonization rate of the specially raised seedling P is greatly improved.
Further, since the specially bred seedling P has a linear shape with no developed branches, it is easy to handle during the planting work, and the workability of transportation and planting is improved.

For reference, FIG. 7 is a top view showing the planting port 31 that has undergone the planting step S5.
It is more preferable that the notch S of the planting port 31 is closed with an adhesive R such as a bond so that a portion other than the portion into which the specially grown seedling P is inserted is not opened.
As a result, when water flows and drains along the non-woven fabric sheet 3 due to wind and rain, rainwater and the like are less likely to enter from the planting port 31, and erosion of the slope 2 can be prevented.
Incidentally, after planting the specially cultivated seedling P, it is necessary to keep the slope 2 in a stable state for a certain period of time until the specially cultivated seedling P takes root on the slope 2. When a large amount of rainwater flows in, it becomes muddy water and the slope 2 easily erodes and collapses, so rooting cannot be expected.
Due to the special breeding seedling P, the diameter of the trunk may be larger than that of the planting port 31, but at this time, the non-woven fabric sheet 3 itself is stretched, and the non-woven fabric sheet 3 and the adhesive R are deteriorated, so that the planting port 31 is formed. It grows larger and the growth of the specially raised seedling P is not hindered.

As described above, this vegetation construction method A does not require the construction of the complicated slope 2, and the number of construction steps is small. Therefore, the construction period is shortened and the cost can be reduced.
Further, even if a large amount of rainwater is used, it can be drained by actively flowing along the non-woven fabric sheet 3.
Moreover, since the non-woven fabric sheet 3 exhibits appropriate water permeability, it is possible to appropriately supply the necessary moisture to the soil on the slope 2.

(Experimental example)
An example of seedlings grown using the special seedling raising step S6 of the present invention is shown below.
(Experiment 1)
FIG. 8 shows the specially raised seedling P obtained in Experiment 1.
As the tree species, Quercus serrata, 54 cm × 21 cm × 25 cm open container 1 was used, and after filling the base soil layer 11 of vermiculite for about 8 minutes, the seeds were sown with an interval of about 2 cm.
Further, the vermiculite embankment layer 12 was provided over the entire surface of the opening container 1 to a thickness of about 2 cm.
The open container 1 was left in a half-shade environment for 12 months.
As a result, a specially raised seedling P having a above-ground portion of 26 cm and a taproot of about 28 cm was obtained.
At this time, as shown in FIG. 9, the development of supporting roots extending laterally with respect to the taproot was not so much observed, and the roots of the adjacent specially bred seedlings P were hardly entangled with each other inside the foundation soil layer 11. I couldn't.
As a result, it was possible to easily manually divide the specially raised seedlings P.

(Experiment 2)
In Experiment 2, wild cherry tree was used as the special breeding seedling P.
The special seedling raising step S6 was carried out by the same method as in Experiment 1 to obtain wild cherry trees having a ground portion of 29 cm and a taproot length of about 32 cm. At this time, the branch branches were short and the development of supporting roots was small, so that the strains could be easily divided.
The vegetation method of the present invention was applied to a slope 2 (300 m ² ) of soil that can be vegetated rather than hard soil.
As the non-woven fabric sheet 3 that directly covers the slope 2, a polyester non-woven fabric sheet 3 (thickness 2 mm, water permeability 1 × 10 ^-3 cm / sec) was used.
The stacking width of the polyester non-woven fabric sheet 3 (width 2 m × length 10 m) was 10 cm, and it was fixed with a U-shaped fixing pin (length 30 cm).
The polyester non-woven fabric sheet 3 was cut out in a Z shape using a knife to make an S and a planting port 31.
Then, a hole was formed in the soil on the slope 2 with a shovel, and wild cherry tree seedlings (main branch 26 cm, taproot 28 cm) were planted.
After planting, the notch S end was pulled so that the slope 2 was not exposed from the planting port 31.
Further, the notch S of the plant opening 31 was closed with an adhesive RR such as a bond so that a portion other than the portion into which the vegetation material was inserted was not opened.
Twelve months after the construction, the wild cherry tree grew to about 55 cm, and weeds hardly grew.
When observing the bottom of the non-woven fabric sheet 3, most of the weeds growing from the soil on the slope 2 were prevented from growing by the non-woven fabric sheet 3.
In addition, the periphery of the stem at the planting port 31 was not exposed, and no dent was formed under the stem due to rapid rainwater erosion.
In addition, 20 months after planting, among the specially grown seedlings P vegetated on the slope, almost none were in a dead state, and the colonization rate was 98%.

Although the preferred embodiment of the present invention has been described above, the present invention is not limited to the above embodiment.

FIG. 9 is a cross-sectional view of a slope 2 showing the vegetation method A according to another embodiment.
In this embodiment, the non-woven fabric sheet 3 was laid directly on the slope 2, but prior to the laying of the non-woven fabric sheet 3, a soil dressing layer 5 was provided on the slope 2 and the soil dressing layer 5 was laid on the slope. The non-woven fabric sheet 3 may be laid so as to be fixed to 2.
The soil dressing layer 5 is formed of soil containing sand and gravel in addition to soil. The composition of the soil dressing layer 5 can be appropriately changed according to the plant species of the specially bred seedling P and the slope 2. Fertilizer, water-absorbing polymer, etc. can be appropriately mixed in the soil constituting the soil dressing layer 5, and the soil on the slope 2 can be improved according to the tree species of the specially grown seedling P. Not required.
This embodiment can be suitably used when the slope 2 is relatively hard soil (on soft rock, etc.). By providing the soil dressing layer 5, the specially cultivated seedling P can easily take root on the slope 2, and the retention rate is improved.
In this case, after removing the grass roots of the slope 2 as much as possible as in the present embodiment, a certain amount of soil dressing is laid on the slope 2 to form the soil dressing layer 5. The thickness of the soil dressing layer 5 varies depending on the size of the specially grown seedling P and the planting hole 21, but is about 10 to 70 cm. In this case, the planting hole 21 is preferably provided at a depth that penetrates the soil dressing layer 5 and reaches the slope 2.
By providing the soil dressing layer 5, the soil properties of the slope 2 are improved, and the colonization rate of the specially grown seedling P on the slope 2 can be improved.
Thereby, the devastation of the slope 2 can be prevented more effectively.

FIG. 10 is a cross-sectional view of a slope 2 showing the vegetation method A according to another embodiment.
In this embodiment, the non-woven fabric sheet 3 laid on the slope 2 has one layer, but the non-woven fabric sheet 3 (lower non-woven fabric sheet 32) is laid on the slope 2 and the soil dressing layer 5 is provided on the non-woven fabric sheet 3. Further, the non-woven fabric sheet 3 (upper non-woven fabric sheet 33) may be laid so as to fix the lower non-woven fabric sheet 32 and the soil dressing layer 5 to the slope 2. In this case, the planting port 31 needs to be provided at the corresponding positions of both the lower non-woven fabric sheet 32 and the upper non-woven fabric sheet 33.
Further, it is preferable that the planting hole 21 is provided at a depth that penetrates the soil dressing layer 5 and reaches the slope 2.
This embodiment can be suitably used when the amount of water in the soil constituting the slope 2 is large and the spring water or the like becomes excess water.
In this case, the lower non-woven fabric sheet 32 serves as a drainage layer, and has the effect of draining excess water downward.
Further, the upper non-woven fabric sheet 33 protects the soil dressing layer 5 and the slope 2 from rainwater and the like, and the upper non-woven fabric sheet 33 drains rainwater and the like.
Further, the lower non-woven fabric sheet 32 can prevent weeds existing on the slope 2 from invading the soil dressing layer 5, and can prevent the growth of the specially grown seedling P from being inhibited.
Even if weeds that have grown in the soil dressing layer 5 invade, the growth of the weeds is inhibited by the upper non-woven fabric sheet 33, and similarly, it is possible to prevent the growth of the specially grown seedling P from being inhibited. ..

In the experimental example, the opening container 1 has a box shape of 54 × 21 × 25 cm, but the size and shape are not necessarily limited to this.

In this embodiment, the non-woven fabric sheet 3 is a rectangular sheet having a size of 2 × 50 m, but the size and shape of the non-woven fabric sheet 3 are not necessarily limited to this.

In this embodiment, the planting mouth forming step S3 and the planting hole forming step S4 are performed after the coating step S1, but the state of the slope 2 and the state of the specially grown seedling P are known in advance, and the planting mouth is formed. If the distance between the 31 can be determined in advance, the planting opening forming step S3 and / or the implanting hole forming step S4 may be performed first, and the coating step S1 may be performed later.
In this case, in the covering step S1, it is necessary to align the planting port 31 or the planting hole 21.

The vegetation method A of the present invention can be applied regardless of the nature of the soil on the slope 2, does not require complicated construction of the slope 2, and requires a small number of construction steps. Therefore, the construction period is shortened and the cost is low.
Further, even if a large amount of rainwater is used, rainwater can be actively flowed along the non-woven fabric sheet 3, so that it is possible to prevent erosion of the slope 2 due to sudden rainwater.
Further, in the special seedling raising step S6, the foundation soil layer 11 using vermiculite suppresses the growth of the supporting root, which is a root extending laterally from the taproot, as much as possible, and the taproot itself grows efficiently.
Therefore, it is easy to divide the roots, and the supporting roots bite into the soil on the slope to stabilize the root mass and improve the retention rate.
It can be applied to various slopes such as rivers, coasts and mountains.

A ... vegetation method S1 ... coating process S2 ... non-woven fabric sheet fixing process S3 ... planting mouth forming process S4 ... planting hole forming process S5 ... planting process S6 ... special seedling raising process P・ ・ ・ Special breeding seedlings P1 ・ ・ ・ Seeds 1 ・ ・ ・ Open container 11 ・ ・ ・ Basic soil layer 12 ・ ・ ・ Filling layer 2 ・ ・ ・ Slope 21 ・ ・ ・ Hole for planting 3 ・ ・ ・ Non-woven fabric sheet 31・ ・ ・ Planting 32 ・ ・ ・ Lower non-woven fabric sheet 33 ・ ・ ・ Upper non-woven fabric sheet 4 ・ ・ ・ Fixture R ・ ・ ・ Adhesive S ・ ・ ・ Notch 5 ・ ・ ・ Customer soil layer

Claims (2)

It is a vegetation method that uses sprout seedlings as special breeding seedlings on the slope.
A coating step of covering the slope with a non-woven fabric sheet and
The non-woven fabric sheet fixing step of fixing the non-woven fabric sheet to the slope, and
A vegetation formation step of forming a vegetation opening on the non-woven fabric sheet,
A step of forming a hole for planting to make a hole for planting the specially grown seedling on the slope directly below the planting port, and
It consists of an planting step of implanting the specially grown seedlings into the planting hole through the planting port .
The specially grown seedlings are seedlings that have been left in water and grown from sunken seeds through a special seedling raising process.
The special seedling raising process
A foundation soil layer is formed in the open container with vermiculite,
The seeds were sown in the foundation soil layer with the distance between the seeds set to 1 to 3 cm without contacting each other.
The seeds are covered with vermiculite to form an embankment layer with a thickness of 1 to 2 cm.
The open container is left outdoors in a half-shade to germinate the seeds and grow into specially grown seedlings of a certain size.
The specially cultivated seedlings in the planting step have a shape in which the development of supporting roots, which are roots extending laterally from the main roots, is suppressed and the main roots themselves grow efficiently, and the main branches grow in the vertical direction, and the main branches grow in the lateral direction. A vegetation method in which the growth of branch branches is suppressed. The vegetation method according to claim 1, wherein the specially grown seedling has a shape in which the lower end of the taproot is sharp.