JP5699291B2 - Vegetation method - Google Patents

Description

  The present invention relates to a vegetation method such as a slope, and more particularly to a vegetation method that can be constructed at low cost without requiring complicated slope construction.

If the land after construction, land development, river embankment, mountain, road, etc., is left exposed, the traces may be eroded, peeled, or sunk, so-called devastation. Easy to convert.
And earth and sand may flow out by a large amount of wind and rain caused by devastation, which is dangerous.
It also looks bad.
For this reason, vegetation is widely applied to rough slopes.
The vegetation stabilizes the soil and prevents the slope from devastation, and the plant is greened, resulting in a natural state and improved appearance.

As a method of this vegetation, for example, as in Patent Document 1, a drainage neutralization plate is fixed to a slope, and a mesh body such as a lath or a net is fixed to the drainage neutralization plate, and then fixed. There is a slope greening method in which a vegetation base is sprayed on the drainage neutralizing plate.
Furthermore, a greening method using a grassproof mat and a grassproof cap as disclosed in Patent Document 2 has been developed.

This tree planting method is a method in which a large number of openings are formed in a grassproof mat laid on a construction surface, and a grassproof cap is embedded from the opening, and the grassproof cap covers the tube portion and the opening. Use the collar part.
The overlapping part of the collar part and the grassproof mat is fixed with an adhesive.
These greening methods use drainable neutralization boards, mesh bodies, vegetation bases, or use grass protection caps and grass protection mats, so the materials used (members used for construction) are also complex. A lot of work man-hours are required for construction.
Therefore, the construction cost increases.
On the other hand, a vegetation planting structure using net material has also been developed, but if a large amount of rain water falls suddenly on the slope, the water does not flow downward along the net material, but is directly absorbed by the slope soil. Therefore, the slope is eroded and vegetation becomes difficult.
In addition, there is a drawback that a hollow is formed around the planted stem and it is difficult to grow.

JP 2003-20652 A JP 2009-17888 A

The present invention has been developed to solve the above problems.
That is, the present invention provides a vegetation method and a ground structure for vegetation that can be easily operated, are inexpensive, and are less likely to erode the slope.

  The inventor of the present invention has completed the present invention through intensive experimental research based on the background of the problems as described above.

That is, the present invention provides (1) a first covering step for covering the slope with the first nonwoven sheet, a guest soil layer forming step for forming a soil layer on the first nonwoven sheet, A second covering step for covering the top with a second nonwoven sheet, a nonwoven sheet fixing step for fixing the first nonwoven sheet to the slope together with the second nonwoven sheet, and a vegetation formation for forming a vegetation for vegetation on the second nonwoven sheet A vegetation method comprising: a step of forming a hole for planting in the soil layer immediately below the planting port; and a planting process of planting a vegetation raw material together with soil into the hole for implantation.

Moreover, this invention exists in the vegetation construction method of the said (1) description which the ( 2 ) and the said vegetation piece consist of a linear notch.

Moreover, this invention exists in the vegetation construction method of the said ( 2 ) description which fixes with an adhesive so that a notch may not be opened after the said planting process ( 3 ).

The invention also relates to (4), so as to wrap the end portion and the end portion of the first nonwoven sheet of soil dressing layer, the (1) according to embed the ends of the periphery of the second nonwoven sheet slope It exists in the vegetation method.

In addition, as long as the objective of this invention is met, the structure which combined the invention of said (1) to ( 4 ) suitably can also be employ | adopted.

The vegetation method of the present invention does not require complicated slope construction and requires fewer construction steps.
Therefore, the construction period is shortened and the cost is low.
In addition, even if there is a large amount of rainwater, it can be actively flowed along the nonwoven fabric sheet, and there is no sudden erosion caused by rainwater.

Moreover, when the said hole for planting consists of a linear notch, when planting a vegetation raw material, an opening part will open according to the size of the diameter of a vegetation raw material (seedling, root stock), and work will be easy.
In addition, since the nonwoven fabric sheet is somewhat stretched, it can be manipulated to reduce the opening after being implanted.

  Further, after the planting process, the excess notch is fixed with an adhesive, thereby preventing water from entering more completely.

FIG. 1 is a block diagram illustrating a vegetation method according to the first embodiment of this invention. FIG. 2 is a cross-sectional view of a slope for explaining the first embodiment of the vegetation method of the present invention. FIG. 3 is a block diagram illustrating a vegetation method according to the second embodiment of this invention. FIG. 4 is a cross-sectional view of a slope for explaining the second embodiment of the vegetation method of the present invention. FIG. 5 is a block diagram illustrating a vegetation method according to the third embodiment of the present invention. FIG. 6 is a slope cross-sectional view for explaining a third embodiment of the vegetation method of the present invention. FIG. 7 is a view showing an example of a notch in the ostium formation step, where (A) shows a Z-shape, (B) shows a cross shape, and (C) shows a V-shape notch. FIG. 8 is a view in which the cutout of FIG. 7 is opened. (A) is a case where the Z-shaped cutout is opened, and the opened vegetation 21 is rectangular, and (B) is a cross-shaped cutout. The vegetation 21 opened when opened shows a rhombus, and (C) shows a triangle when the opened vegetation opened when a V-shaped notch is opened. FIG. 9 is a schematic diagram illustrating a construction surface by the vegetation method according to the first embodiment of the present invention.

  In the vegetation method of the present invention, the vegetation material P as a starting material is a plant that is desired to be vegetated in the future, and has various forms such as flowers, trees, seeds, and seedlings.

(First embodiment)
The vegetation method of this embodiment includes a covering step for covering the slope with the first nonwoven sheet 2, a first nonwoven sheet fixing step for fixing the first nonwoven sheet 2 to the slope, and a vegetation on the first nonwoven sheet 2. For example, a planting formation process for forming a planting port 21, a planting hole forming process for forming a hole for planting directly below the planting 21, and a planting process for planting the vegetation raw material P into the planting hole.

  FIG. 1 is a block diagram showing the steps of this vegetation method, which will be described in order for each step.

1) Covering process In this Embodiment, if the part (here slope) used as construction object is not hard soil but soil which can be vegetated, it is applicable.
In addition, when grass roots are included in the sloped soil, it is preferable to remove as much as possible.
Then, the first nonwoven fabric sheet 2 is laid on the slope 1.
And the edge part 22 around the 1st nonwoven fabric sheet 2 is embedded in the soil of the slope 1. FIG.
By the way, when laying the 1st nonwoven fabric sheet 2, a construction area is expanded by connecting many sheets of nonwoven fabric sheets 2 of the sheet-like piece which have fixed width in plane shape.
In that case, it is preferable that the end portions of the nonwoven fabric sheet 2 are overlapped and bonded.
As the first non-woven fabric sheet 2, as will be described later, a sheet that allows rainwater to flow along the slope and allows some moisture to pass therethrough is employed.
It is also important to prevent grass buds extending upward from the slope 1 (that is, to prevent grass).
For this reason, as the first nonwoven fabric sheet 2, for example, a nonwoven fabric made of synthetic fibers is preferably used.
The first nonwoven sheet 2 may be corroded in a state where the vegetation raw material P has grown to some extent after the construction work.

2) 1st nonwoven fabric sheet fixing process The 1st nonwoven fabric sheet 2 is fixed to the slope 1 using the stop pin 4 etc. (fixing means).
In this case, usually, for example, the stop pin 4 is driven into the sloped soil from above the first nonwoven fabric sheet 2.
As the set pin 4, a nail-shaped pin or a U-shaped pin is used.
The first non-woven fabric sheet 2 is exposed to the outside air and may be rolled up by wind and rain, etc., and can be prevented by fixing it with the stop pin 4.
In addition, it is preferable to drive the 1st nonwoven fabric sheet 2 also into the overlap part of edge parts.
Moreover, the edge part 22 around the 1st nonwoven fabric sheet 2 is embedded in soil by a fixed distance.
The 1st nonwoven fabric sheet 2 used here is various as long as water etc. can be flowed down and drained along it, water can pass through to some extent, and it has the function of grass prevention. Nonwoven fabric sheets can be used.
Incidentally, the non-woven fabric sheet has moderate water permeability, unlike the net, but does not allow water to pass rapidly.
Moreover, as a material of a nonwoven fabric sheet, what was formed of synthetic fibers (polyester, rayon, etc.) is preferable.
Unlike natural fiber, it has the advantage that it retains its shape for several years after construction and has good shape retention.
The water permeability is preferably 1 × 10 ⁻³ to 10 ⁻⁵ (cm / sec).
Therefore, even if it rains suddenly, rainwater is induced to flow downward along the first nonwoven fabric sheet 2 (along the slope). It encourages discharge.

3) Planting formation step This is a step of forming the planting port 21 for vegetation in the first nonwoven fabric sheet 2.
The reason why the vegetation 21 is formed is that the vegetation raw material P is planted upright on the slope 1 through the vegetation 21.
The planting 21 is made of a linear cutout S, and the cutout of the cutout S is preferably as thin as possible.
It is preferable to cut the planting 21 using scissors or a knife.

FIG. 7 is a view showing an example of the cutout S, where (A) shows a Z-shape, (B) shows a cross-shape, and (C) shows a V-shape.
The notch S can be properly used depending on the size of the vegetation raw material P.

FIG. 8 shows a view in which the notch S of FIG. 7 is opened for reference, but it can be seen that the shapes of the opened vegetation 21 are different.
(A) is the case where the Z-shaped cutout S is opened, the opened vegetation 21 is a rectangle, (B) is the case where the cross-shaped cutout S is opened, and the opened vegetation 21 is a rhombus, (C) is a case where the V-shaped cutout S is opened, and the opened vegetation 21 shows a triangle.
In particular, the Z-shaped notch S can be formed with a single stroke and formed into a rectangular vegetation 21, so that it can handle a large root mass and is also efficient in construction.
However, the size and shape of the vegetation 21 can be adjusted by changing the degree of opening and closing.
Further, as will be described later, since the nonwoven fabric sheet is stretched somewhat, it is possible to make the extra planting 21 as small as possible by pulling the notched end after construction.

4) Hole formation process for planting A hole for planting the vegetation raw material P into the sloped soil is dug just below the planting port 21 formed in the first nonwoven fabric sheet 2.
Here, the vegetation raw material P to be planted includes various forms such as flowers, trees, seeds, seedlings, and the like.
This planting hole varies depending on the size of the root mass of the vegetation raw material P. For example, the diameter is about 5 cm to 20 cm for flowers, and about 40 cm to 80 cm for medium tree seedlings, and the depth is about the same. It is.
That is, since the vegetation raw material P usually has a root nodule, it only needs to be large enough to accommodate this.
A specific method of making a hole for implantation is to create a space when a transplanting trowel (such as a scoop) is pushed into the soil on the slope through the planting 21 and moved laterally by a certain angle, and this portion becomes a hole.
Thus, the hole for implantation forms a space as a hole rather than digging.

5) Planting process The vegetation raw material P is planted from the planting port 21 formed in the first nonwoven fabric sheet 2 into the planting hole on the slope 1.
In this case, since the planting hole formed by the planting hole forming step and the planting port 21 of the first nonwoven fabric sheet are in a corresponding position, the vegetation raw material P having a root mass together with soil in the planting hole through the planting port 21 To plant.
Then, press around the planted area to harden it.
Here, after planting the root nodules, the first nonwoven sheet 2 stretches a little when pulled, so pulling the notched end to make the planting 21 around the stem as small as possible so that the soil is not exposed. Good.
More preferably, the notch S of the planting 21 is closed with an adhesive R such as a bond so as not to open a portion other than the portion where the vegetation material P is inserted (see FIG. 9B).
This is because rainwater or the like is difficult to enter from the vegetation port 21 when water flows and drains along the nonwoven fabric sheet due to wind and rain.
Incidentally, it is necessary to keep the slope stable for a certain period of time after planting the vegetation material P, but it becomes muddy water if a large amount of rainwater flows from the vegetation port 21. The surface is easily eroded and cannot be rooted.
As described above, this vegetation method does not require complicated slope construction, requires fewer construction steps, shortens the construction period, and reduces costs.
Even if there is a large amount of rainwater, it can be drained by actively flowing along the nonwoven fabric sheet.
And since a nonwoven fabric sheet shows moderate water permeability, it can supply the water | moisture content required also to slope soil suitably.

(Ground structure for vegetation)
Thus, a vegetation ground structure as shown in FIG. 2 is formed.
The ground structure for vegetation includes a first nonwoven sheet 2 covering the slope 1, a vegetation 21 formed on the first nonwoven sheet 2 at a constant interval (may be an indefinite interval), and a slope 1 from the vegetation 21. It consists of the vegetation raw material P planted in.
Here, the first non-woven fabric sheet 2 is fixed to the slope 1 by fixing means such as a stop pin 4 and is not rolled up by wind and rain.
In particular, after planting the vegetation raw material P, the area around the vegetation 21 tends to be pulled outward and the vegetation 21 tends to open.
Therefore, in the nonwoven fabric sheet fixing step described above, it is preferable that the stop pin 4 driven near the planting port 21 is driven outward in an inclined state (that is, a direction away from the vegetation raw material as it is driven). This can prevent the opening 21 from opening.
Moreover, even if rainwater falls on the slope 1 intensively, it flows down the slope along the first nonwoven fabric sheet 2.
In this case, as described above, the extra vegetation 21 outside the vegetation raw material P is blocked so that the sloped soil is not exposed, so that rainwater is prevented from entering from the vegetation 21 and a depression is formed. Can not.
In this way, rainwater does not rapidly invade the sloped soil, and the problem that the slope 1 is eroded and collapses does not occur.

(Second Embodiment)
The vegetation method of this embodiment includes a soil layer forming step for forming the soil layer 1A on the slope 1, a covering step for covering the soil layer 1A with the first nonwoven sheet 2, and a first nonwoven sheet 2 A first nonwoven sheet fixing step for fixing the surface 1 to the slope 1, a planting formation step for forming a vegetation port 21 for vegetation on the first nonwoven sheet 2, A planting hole forming step for making a hole for the planting, and a planting step for planting the vegetation raw material P together with soil into the planting hole.
This vegetation method is effective when applied when the slope is relatively hard soil (soft rock or the like).

FIG. 3 is a block diagram showing the steps of this vegetation method, which will be described sequentially for each step.
This method is different from the first embodiment in that the customer soil layer 1A is formed on the slope 1 in advance.
When the slope is relatively hard soil, the vegetation raw material P is less likely to take root, and therefore, such a soil layer 1A is provided.

1) Guest soil layer forming step First, it is preferable to remove as much as possible the grassroots of the portion to be constructed (the slope here).
Then, a certain amount of soil is laid on the slope 1 to form the soil layer 1A.
As described above, this is formed because the vegetation material P is difficult to grow when the slope is relatively hard soil.
Although the thickness which piles up the soil layer 1A varies depending on the size of the vegetation raw material P and the hole for planting, it is about 10 cm to 70 cm.
For example, it is small for flowers, but naturally larger for tree seedlings.
The guest soil layer is formed by soil containing sand and small gravel in addition to soil, but it is not necessary to dare to mix soil improver or fertilizer.

2) Covering step The first nonwoven fabric sheet 2 is laid on the soil layer 1A.
Here, when the first nonwoven fabric sheet 2 is laid, the construction area is increased by connecting a large number of the first nonwoven fabric sheets 2 in a sheet shape having a certain width in a plane.
Also in this case, it is preferable that the end portions of the first nonwoven fabric sheet 2 are overlapped and bonded.
In particular, the end 22 around the first nonwoven fabric sheet 2 is embedded in the slope 1 at a certain depth so that the end of the soil layer 1A is wrapped.
The 1st nonwoven fabric sheet 2 plays the role which drains rain water etc. along the 1st nonwoven fabric sheet 2, and eliminates it.
And even if there is a weed that extends from the sloped soil to the soil layer 1A, the first nonwoven fabric sheet 2 prevents further growth.

3) 1st nonwoven fabric sheet fixing process The 1st nonwoven fabric sheet 2 is fixed to the slope 1 using fixing means, such as 4 stop pins.
In this case, the stop pin 4 is driven into the soil on the slope 1 so as to penetrate the customer soil layer 1A from above the first nonwoven fabric sheet 2.
As the retaining pin 4, a nail-shaped pin or a U-shaped pin is used.

4) Planting formation step This is a step of forming the planting port 21 for vegetation in the first nonwoven fabric sheet 2.
As described above, the vegetation 21 is composed of a linear cutout S, and for example, a cross, Z-shape, or V-shape is employed.
The cut end should be close to a line and as thin as possible. The cutting end 21 is preferably cut using a pinch or knife.

5) Planting hole forming step A hole for planting the vegetation raw material P is dug in the above-mentioned soil layer 1A just below the planting port 21.
Specifically, the hole is made by pushing a transplanting trowel (scoop) into the soil layer 1A through the planting port 21 and moving it laterally at a certain angle, and this portion becomes a hole for implantation.
As described above, for example, the diameter of the planting hole is about 5 cm to 10 cm for flowers, and about 15 cm to 20 cm for medium-sized tree seedlings.

6) Planting process The vegetation raw material P is planted from the planting port 21 into the planting hole of the soil layer 1A.
In this case, the vegetation raw material P is put together with the soil through the planting hole 21 into the planting hole formed by the planting hole forming step.
Implanting is easy because the hole for implantation is formed so as to correspond to just below the planting 21.
Then, press around the planted area to harden it.
As described above, after the root mass is planted, the first nonwoven fabric sheet 2 is stretched a little when pulled, so the soil is not exposed by pulling the notched end to make the planting 21 around the stem as small as possible. It is good to do so.
Further, the notch S is preferably closed with an adhesive R so as not to open a portion other than the portion where the vegetation material P is inserted.

(Ground structure for vegetation)
Thus, a vegetation ground structure as shown in FIG. 4 is formed.
The ground structure for vegetation includes a soil layer 1A formed on the slope 1, a first nonwoven sheet 2 covering the soil surface 1A, and a vegetation 21 formed on the first nonwoven sheet 2 at regular intervals. , And vegetation raw material P planted in the soil layer 1A from the vegetation port 21.
Here, the first nonwoven fabric sheet 2 is fixed to the slope 1 by a fixing means such as a stop pin 4.
Since the soil layer is provided, the vegetation material P is grown even if the slope is hard. Since there exists the 1st nonwoven fabric sheet 2, even if the weed bud contained in the soil layer will extend, it will be stopped here.
Moreover, the 1st nonwoven fabric sheet 2 plays the role which flows rain water etc. downward along this, On the other hand, since it has water permeability, it provides moderate water | moisture content 1A to the soil layer 1A.

(Third embodiment)
The vegetation method of this embodiment includes a first covering step for covering the slope 1 with the first nonwoven sheet 2, a guest soil layer forming step for forming the soil layer 1B on the nonwoven sheet, the customer soil layer A second covering step for covering the top of 1B with the second nonwoven sheet 3, a nonwoven sheet fixing step for fixing the first nonwoven sheet 2 to the slope 1 together with the second nonwoven sheet 3, and a planting for vegetation on the second nonwoven sheet 3 Planting step for forming the mouth 31, planting hole forming step for making a hole for planting in the soil layer 1B directly below the planting port 31, planting step for planting the vegetation raw material P together with soil in the planting hole It becomes more.

  FIG. 5 is a block diagram showing the steps of this vegetation method, which will be described in order for each step.

1) 1st covering process This vegetation method is suitable when the part (here slope) used as construction object is comparatively hard soil like 2nd Embodiment.
First, the first nonwoven fabric sheet 2 is laid on the slope 1.
In this case, even if the end portions of the first nonwoven fabric sheet 2 are overlapped, it is not necessary to bond them.
This 1st nonwoven fabric sheet 2 prevents the weed bud contained in the soil of the slope 1 from growing, and prevents it from extending in the customer soil layer 1B described below.
This does not inhibit the growth of the vegetation raw material P to be planted in the customer soil layer 1B described later.
As the 1st nonwoven fabric sheet 2, the thing like the 1st nonwoven fabric sheet 2 mentioned above is used.
Moreover, this 1st nonwoven fabric sheet 2 plays the role which also guide | induces and drains with respect to the surplus water which springs up from underground, so that it may mention later.
In this case, since this 1st nonwoven fabric sheet 2 is pressed down with the load of the soil layer formed at the next process, it is not necessary to fix the 1st nonwoven fabric sheet 2, and driving of stop pin 4 grade | etc., Can be abbreviate | omitted.

2) Guest soil layer forming step The customer soil is laid on the first nonwoven fabric sheet 2 to form the customer soil layer 1B.
The thickness which piles up the soil layer 1B here is also about 20 cm to 80 cm.
The guest soil layer is on the first non-woven fabric sheet 2 and is separated from the slope and becomes a soil for further growth. Therefore, a relatively large layer thickness is preferred compared to the second embodiment.

3) Second covering step Next, the second non-woven fabric sheet 3 is further laid on the soil layer 1B.
In this case, the second nonwoven fabric sheet 3 plays a role of flowing rainwater or the like along the second nonwoven fabric sheet 3.
Moreover, even if there is a weed extending from the sloped soil to the soil layer 1B, the second nonwoven fabric sheet 3 reliably prevents the upward growth.
On the other hand, the peripheral edge portion 32 of the second nonwoven fabric sheet 3 is embedded in the slope 1 so as to wrap the end portion of the soil layer 1B and the end portion of the first nonwoven fabric sheet 2.
As a result, the customer soil layer 1B is partitioned between the first nonwoven fabric sheet 2 and the second nonwoven fabric sheet 3 and can set a unique growing environment.

4) 2nd nonwoven fabric sheet fixing process The 2nd nonwoven fabric sheet 3 is fixed to a slope with the stop pin 4 etc. (fixing means).
In this case, the stop pin 4 is driven so as to penetrate the slope 1 through the first nonwoven sheet 2 from above the second nonwoven sheet 3.
This is to prevent the second nonwoven fabric sheet 3 from being exposed to the outside air and being swollen by wind and rain.
It is preferable that the second nonwoven fabric sheet 3 is also driven into the overlapping portion between the end portions.

5) Planting formation process,
This is a step of forming a vegetation opening 31 for vegetation in the second nonwoven fabric sheet 3.
As described above, the vegetation 31 is made of a linear notch S, and for example, a Z-shaped, cross-shaped, or V-shaped one is adopted, and the cut end is close to a linear shape and becomes as thin as possible. Cut with a pinch or knife.

6) Hole formation process for planting A hole for planting the vegetation raw material P is formed in the above-mentioned soil layer 1B just below the planting port 31.
As described above, as described above, when a transplanting trowel (scoop) is pushed into the customer soil layer 1B through the planting port 31 and moved in a lateral direction by a certain angle, a space is created, and this portion becomes a planting hole.
The size of the hole has been described in the above embodiment.

7) Planting process The vegetation raw material P is planted from the planting port 31 into the planting hole of the soil layer 1B.
In this case, the vegetation raw material P is planted together with the soil through the planting port 31 into the planting hole formed by the planting hole forming step.
Then, press around the planted area to harden it.
As described above, after planting the root nodules, the second nonwoven fabric sheet 3 stretches a little when pulled, so pulling the notched end to make the planting 31 around the stem as small as possible so that the soil is not exposed. It is good to do so.
Further, as described above, the notch S is preferably closed with the adhesive R so as not to open the part other than the part where the vegetation material P is inserted.
As described above, this vegetation method does not require complicated slope construction, and the number of construction steps is small, and the cost can be reduced.

(Ground structure for vegetation)
Thus, a vegetation ground structure as shown in FIG. 6 is formed.
This vegetation ground structure includes a first nonwoven sheet 2 covering the slope 1, a customer soil layer 1B formed on the first nonwoven sheet 2, and a second nonwoven sheet covering the customer soil layer 1B. 3, vegetation openings 31 formed at regular intervals in the second nonwoven fabric sheet 3, and vegetation raw material P planted from the vegetation opening 31 into the soil layer 1 </ b> B.
The 1st nonwoven fabric sheet 2 and the 2nd nonwoven fabric sheet 3 are being fixed to the slope 1 with the stop pin 4 grade | etc., (Fixing means).
Since the 1st nonwoven fabric sheet 2 exists in the lowest level, even if the weed bud contained in the sloped soil will extend, it will be stopped here.
And even if there is a weed that has extended from the sloped soil to the customer soil layer 1B, the second nonwoven fabric sheet 3 reliably prevents the upward extension.
Moreover, since the 1st nonwoven fabric sheet 2 exists under the customer soil layer 1B, it will be located in the level embedded from the surface.
For this reason, at this position, side water or the like rises from below and tends to stay as surplus water.
However, the presence of the first nonwoven fabric sheet 2 causes the surplus water to be drained downward by the first nonwoven fabric sheet 2 serving as a drainage layer.
Moreover, since the 2nd nonwoven fabric sheet 3 plays the role which flows rain water etc. downward along this, and also has water permeability, it provides moderate water | moisture content to the soil layer 1B.

The following construction experiment was conducted.
(Experiment 1)
This construction example is an example in which the method of the first embodiment is adopted.
The vegetation method of the present invention was applied to a slope (300 m ² ) of soil that can be vegetated instead of hard soil (see FIG. 9).
As the first nonwoven fabric sheet that directly covers the slope, a polyester nonwoven fabric sheet (thickness 2 mm, water permeability 1 × 10 ⁻³ cm / sec) was used. The overlap width of the polyester nonwoven fabric sheet (width 200 cm × 1000 cm) was 10 cm, and was fixed with a U-shaped set pin (length 30 cm).
The polyester non-woven sheet was cut into a Z shape using a knife to make a vegetation.
A hole was formed in the sloped soil with a scoop, and a seedling of Yamazakura (height 10 cm) was planted as a vegetation material.
After planting, the notched edge was pulled so that the soil layer was not exposed from the planting port.
Further, the notch of the vegetation was closed with an adhesive R such as a bond so that the part other than the part into which the vegetation material was inserted was not opened (see FIG. 9B).
After 12 months of construction, Yamazakura grew to 20-30 cm, and almost no weeds were growing.
When the bottom of the first non-woven fabric sheet was observed, most of the weeds extending from the sloped soil were prevented from being extended by the first non-woven fabric sheet.
In addition, the area around the stem at the vegetation was not exposed, and there was no pit due to rapid rainwater erosion.

(Experiment 2)
This construction example is an example in which the method of the second embodiment is adopted.
The vegetation method of the present invention was applied to a slope (300 m ² ) of a relatively hard soil.
A polyester nonwoven fabric sheet (thickness 2 mm, water permeability 1 × 10 ⁻³ cm / sec) was used as the first nonwoven fabric sheet covering the customer soil layer. The overlap width of the polyester nonwoven fabric sheet (width 200 cm × 1000 cm) was 10 cm, and was fixed with a U-shaped set pin (length 35 cm).
The soil layer containing crusher orchid (sand) was used as the guest soil layer, and it was formed to a layer thickness of 20 cm.
The polyester non-woven sheet was cut into a Z shape using a knife to make a vegetation.
A hole was formed in the soil layer with a scoop, and a seedling of Yamazakura (height 10 cm) was planted as a vegetation material.
After planting, the notched edge was pulled so that the soil layer was not exposed from the planting port.
Twelve months later, the wild cherry tree grew to a height of 20-30 cm, and almost no weeds were growing.
Moreover, when the bottom of the 1st nonwoven fabric sheet was observed, the weeds extended from the sloped soil had reached the customer soil layer, but many of them were prevented from extending by the 1st nonwoven fabric sheet.
Even in the observation during heavy rain, it was visually recognized that rainwater flowed downward along the first nonwoven fabric sheet and drained.
In addition, the periphery of the stem at the vegetation was not exposed, and there was no dent due to sudden erosion of rainwater.

(Experiment 3)
This construction example is an example in which the method of the third embodiment is adopted.
This construction example is an example in which the method of the third embodiment is adopted using the same polyester nonwoven fabric sheet and vegetation raw material at the same slope as in Experiment 2.
The guest soil layer was formed to a thickness of 30 cm, and seedlings of Yamazakura (height 10 cm) were planted as vegetation raw materials.
After planting, the notched edge was pulled so that the soil layer was not exposed from the planting port.
Twelve months later, the wild cherry tree grew to a height of 20-30 cm and no weeds were growing.
Moreover, when the bottom of the 1st nonwoven fabric sheet was observed, most of the weeds which extended from the soil of the lowest slope were prevented from extending by the 1st nonwoven fabric sheet.
Moreover, when the lower part of the second nonwoven fabric sheet was observed, weeds that penetrated through the first nonwoven fabric sheet to the soil layer were prevented from being reliably extended by the second nonwoven sheet.
In addition, the periphery of the stem at the vegetation was not exposed, and there was no dent due to sudden erosion of rainwater.

Although the present invention has been described above by taking the embodiment as an example, the present invention is not limited to the above-described embodiment, and various modifications can be made.
Regardless of whether it is rubble, earth or sand, or clay, the slope subject to the construction of the present invention is not restricted.
The slope of the slope has at least a so-called water gradient.
For example, various vegetation materials can be used as long as they can be planted and grown on the sloped soil and the soil layer.
Needless to say, the first non-woven fabric sheet and the second non-woven fabric sheet can be corroded when the vegetation raw material P is grown to some extent after construction.
Further, on the first nonwoven fabric sheet 2 of the first embodiment, on the first nonwoven fabric sheet 2 of the second embodiment, and on the second nonwoven fabric sheet 3 of the third embodiment, respectively. It is also possible to spray etc.
Since turf seeds are easily held by these nonwoven fabric sheets, they have good rooting.
Moreover, the thickness of the soil layer of 1st Embodiment and 2nd Embodiment is not necessarily restrained by the numerical range mentioned above.

DESCRIPTION OF SYMBOLS 1 ... Slope 1A ... Soil layer 1B ... Soil layer 2 ... 1st nonwoven fabric sheet 21 ... Port 22 ... End 3 ... 2nd nonwoven sheet 31 ... Port 32 ... End 4 ... Fixing means (stop pin)
P ... Vegetation raw material R ... Adhesive S ... Notch

Claims (4)

A first covering step for covering the slope with the first nonwoven sheet, a soil layer forming step for forming a soil layer on the first nonwoven sheet, and a second nonwoven sheet covering the soil layer with the second nonwoven sheet. 2 covering step, non-woven sheet fixing step for fixing the first non-woven fabric sheet to the slope together with the second non-woven sheet, vegetation forming step for forming a vegetation for vegetation on the second non-woven fabric sheet, just below the vegetation A vegetation method comprising a planting hole forming step of making a hole for planting in the customer soil layer, and a planting step of planting a vegetation raw material together with soil into the planting hole. The vegetation method according to claim 1, wherein the vegetation is formed by a linear notch.   The vegetation method according to claim 2, wherein after the planting step, the notch is fixed with an adhesive so as not to open. The vegetation method according to claim 1, wherein the end portion of the second non-woven fabric sheet is embedded in the slope so as to wrap the end portion of the soil layer and the end portion of the first non-woven fabric sheet.

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