KR101885094B1 - Formation methods of Functional forest - Google Patents

Abstract

The present invention relates to a method for implementing a functional forest capable of providing various functions to cope with climate change or to implement eco-friendly functions. On-site investigation and restoration models are set up to realize the forest having various functions, and damaged lands are restored to a simple ecological forest by optimizing correcting and restoring methods accordingly. Further, the forest can be implemented as a functional forest having a function of coping with climate change, preventing air pollution, preventing forest disaster, or having a function of eco-friendly health promotion forest.

Description

Formation methods of functional forests with various functions

The present invention relates to a method for implementing functional forests capable of providing various functions to cope with climate change or to implement eco-friendly functions.

Forests have a variety of environmental preservation functions, such as rehabilitation of water sources and prevention of disasters, based on the existence of living creatures. They also contribute to "biodiversity conservation" that is being carried out at the district level by actively preserving plants and animals.

In general, it is highly desirable that forest ecosystems are natural vegetation transitions in the absence of human intervention. However, in the case of forests or forests that have not been recently managed, the biotic vegetation transgression by foreign plants such as prickly pests has destroyed the surrounding forest ecosystem, and the damage caused by natural disasters such as artificial development and landslides The restoration of the simple plantation is disturbing the surrounding forest ecosystem.

In addition, as the income level of the people continues to increase, the public interest in the quality of life is heightened and interest in forests is also increasing. Therefore, the Korean Forest Service is carrying out various researches to create forests that can realize the various functions of forests by shifting the forests from the purpose of simple wood production.

Therefore, forests with specific functions for unmanaged forests or restoration of damaged areas inside the forests need to be actively managed and promoted in order to activate their functions without disturbing existing forest ecosystems. .

Techniques related to the composition and restoration of existing forests have been adapted to the general form of restoration that can restore the form of damage to the forest. Recently, various environmental issues such as pollution problem and climate change are increasing the necessity of implementing ecological forests with new functions. However, until now, the method of forest restoration and restoration has merely identified plant species similar to existing trees in the damaged forest, When planted, it is adapted to improve the growth and growth, and there is a limit to responding to such a new environmental issue.

Patent No. 10-0805188

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to set up a field survey and restoration model for realizing functional forests implementing various functions, In addition to restoring damaged areas to forests, it also provides technologies that can be implemented as functional forests that function as climate change, prevention of air pollution, forest disaster prevention, or environmentally friendly health promotion forests.

As a means for solving the above-mentioned problems, in an embodiment of the present invention, a restoration goal setting step of setting a model of a setting target functional forest with respect to a functional forest construction site; A suitability verification step of verifying suitability of a restoration target through on-site investigation of the target site set as the set restoration target; A restoration material selection step of determining the functional forest model after the suitability verification and selecting the restoration material; And a construction step of constructing a functional forest model corresponding to a predetermined restoration target for the target site.

According to the embodiment of the present invention, in setting up a field survey and restoration model for implementing functional forests implementing various functions, and optimizing the correction and restoration methods, restoration of a damaged forest with a simple ecological forest is further achieved, It can be implemented as a functional forest with the function of forest change, prevention of air pollution, prevention of forest disaster, and environment-friendly health promotion forest.

In particular, when a functional forest is implemented by selecting a restoration model, it is possible to change the function of a defective forest having a damaged area or existing forests to a restoration forest having various functions, or alternatively, By replacing them with post-functional trees, it is possible to economically realize functional forests that best match the characteristics of the target area to be restored.

FIG. 1 is a view showing a construction process of a functional forest composition method having various functions according to an embodiment of the present invention, and FIG. 2 is a block diagram showing a detailed process of FIG.
Fig. 3 shows an example of the status survey of the target site.
4 to 6 are conceptual diagrams illustrating a construction process according to an embodiment of the present invention.
7 is a conceptual diagram showing the structure of the organic block.
FIGS. 8 and 9 illustrate application examples of the organic block of FIG. 7. FIG.

Hereinafter, the configuration and operation according to the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description with reference to the accompanying drawings, the same reference numerals denote the same elements regardless of the reference numerals, and redundant description thereof will be omitted. The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

1 is a view showing a construction process of a functional forest composition method (hereinafter referred to as 'the present invention') having various functions according to an embodiment of the present invention. FIG. 2 is a view showing a construction process It is published.

1 and 2, the present invention relates to a restoration target setting step of setting a model of a setting target functional forest with respect to a functional forest composition target site, and a restoration target setting step of performing a field investigation on the target site set as the set restoration target A conformity verification step to check the suitability of the restoration objective, a functional forest model after the conformity verification, a selection step of restoration materials and construction methods for selecting restoration materials and construction methods, and a functional forest model according to predetermined restoration goals And a construction step for constructing the building.

The gist of the embodiment of the present invention is to restore the target site (hereinafter, referred to as 'function forest site') which is intended to implement the degradation or functional forest, The objective of the present invention is to provide an efficient function forest restoration method which can set a goal (implementing functional forests conforming to specific functions) and to implement a method of restoring and verifying conformity thereto. Hereinafter, the processes of the present invention will be described in order.

1. Restore Goal Setting Steps

Functional forests can be implemented in a way that restores damaged areas to provide forest functions and implement new forests, or utilize the functionality of existing forests or reduce existing trees to functional trees and implement them as new functional forests. .

In the present invention, a preliminary investigation is performed on a functional forest site to determine whether the functional forest is to be constructed with a functional structure (hereinafter, referred to as a 'restoration target'). For example, referring to FIG. 2, when a damaged area occurs in the forest, a type of damage (such as spot damage, area damage, shipment damage, etc.) ) And make it possible to grasp policy object ratings through ecological natural maps or biotop maps.

As shown in FIG. 3, in the case of the spot-damaged area, the vegetation of the surrounding area is surveyed, and the area damaged is examined at four or more vegetation around the defective area. In the case of the defective area , And two or more vegetation around the damaged area by shipment.

Through these preliminary surveys, we will set up restoration targets for what functional forests to implement as functional forests.

The restoration targets of the present invention largely include climate change response forests, air pollution abatement forests, forest disaster prevention forests, and diversity promotion forests as shown in Table 1 below. Of course, such a restoration target may be added to a major change in functionality depending on environmental changes or goals.

Restoration targets classified into these major categories can be further refined. For example, as shown in Table 1, in the case of a forest set as a restoration target as a result of a preliminary investigation on a functional forest, it can be implemented with various criteria.

{Table 1: Restoration goal setting criteria}

For example, the above-mentioned forests to cope with climate change can provide a carbon-abatement forest when the share of the target species classified by the carbon accumulation function is 30% or more of the total species species density, As shown in Table 2, in the southern region, when the species density of all the species in the range of 90 to 110 on the basis of the gentility index is more than 30% for two species of tree species, Of the total tree species in the range of more than 30 species of tree species can be created as forests to mitigate climate change impact. In the present embodiment, the southern region defines Honam region and Kyungnam region, and the central region includes Chungcheong region, Gyeonggi Province, and Kangwon region.

{Table 2: Representative Species of Forest Setting Criteria for Mitigating Climate Change Impact}

The air pollution abatement forest of the present invention can be made into an air pollution prevention forest when two or more kinds of species occupying the functional forest formation target occupy 20% or more of the density of the total species, When two or more kinds of species occupying the forestation site occupy more than 20% of the density of the whole species, it can be implemented as a fine dust reduction forest.

In addition, the above-mentioned forest disaster prevention forest can be implemented in the case where the above-mentioned functional forest area is located in the valley part, one or more of the vegetation native to the corresponding area occupies more than 50% And a wilderness prevention forest which can be realized when at least one species that grows in the vicinity of the functional forest promotion site grows in a strip shape.

The diversity-promoting forest may be a biodiversity-enhancing forest applicable to the case where the vegetation of the surrounding forest of the functional forest formation site has a multi-layer structure, or a surrounding forest of the functional forest- Of the lime mining recovery forest which can be implemented when the lime content of the forest is greater than 30%, and the lime content of the soil of the functional forest is smaller than 10 ~ 50% And can be implemented with a configuration including at least any one or more of them.

The configuration of the detailed target forest according to the setting reference of the restoration target in the present invention may be set to a structure that functions as a function on the functional forest composition target site or to be implemented as two or more functional forests among the detailed models of the functional forest described above It can also be set.

It is also possible to implement functional forests by granting targets from the client without prior investigation.

2. Compliance verification step

In the case of the functional forest according to the present invention, it is desirable to set the restoration model through the preliminary investigation, and then to conduct the field investigation to verify the fitness of the functional forest.

In the case of a large area, it is necessary to set up a region (geographical location, classification by terrain according to altitude), and to make ecological naturalness and greenery naturalness map So that it can be analyzed separately. Furthermore, considering the relation with the nearby urban area, it will be able to identify the distance and influence from the city center and to consider the information about the major ecological axis.

That is, as shown in FIG. 2, it is possible to grasp the surrounding vegetation (woody herbaceous herbaceous plant species and auxiliary constituent species) for the functional forest formation site, obtain information on the soil environment by grasping the organic matter content and soil quality, And to examine the appropriateness of the restoration target. Of course, in this case, the restoration target (kind of the functional forest) can be reset if it is not suitable for the setting of the restoration target set after the initial preliminary investigation, and if necessary, the specific introduction species or seed, vegetation And the like.

{Table 3: Possible classification of species by restoration target}

As for the species that can be applied to the detailed restoration target of functional forest according to the present invention as shown in Table 3, the species that can be introduced into the carbon-abatting forest are as follows: Persimmon tree, Zelkova tree, , Mica, lacquering, flower gardenia, azalea, and the like.

Furthermore, the species that can be introduced into the southern part of the forest in the climate change shock mitigation forest are the oak tree, the crow tree, the nado tree, the papaya tree, the camellia tree, the stamina tree, the aspen tree, the mountain mulberry tree, the oak tree, It can be implemented to include at least one selected from timber, timber oak, timber camellia, oak wood, oak wood, oak wood, and hair oak wood. In the central area, the oak wood, oak wood, It can be implemented to include at least one species selected from wood, ash tree, bugae flower, true tree, mountain mulberry, oak, pine, oak, camellias, shrubs, and magpie.

In addition, the species that can be introduced into the air pollution prevention forest include at least one species selected from birch, maple, pine, pine, pine, weed, and oak.

Further, the species which can be introduced into the fine dust-reducing forest of the present invention include at least one species selected from pellets, hornblende, hazelnut, bark, oak, oak, .

In addition, the species that can be introduced into the forests of the source forest include at least one species selected from the group consisting of oak, oak, and birch. In addition, it can be implemented with a structure including a quince tree and a pine tree. Can be introduced into at least one selected from the group consisting of oyster oak, camellia oak, Araliaceae, Aspergillus, Ginkgo, oak, and acacia.

The species that can be introduced into the biodiversity promotion forest are at least one selected from the group consisting of oak, oak, oak, oak, bole, azalea, hawthorn, And the species that can be introduced into the forest for promoting the diversity of the landscape include at least one species selected from birch, alfalfa, plum tree, maple, cherry tree, azalea and azalea. .

Also, in the case of the soil used for restoration of the destruction site caused by the development of the lime mine which causes the destruction and breakage of the major ecological axis in the present invention, in the realization of the lime mine recovery forest, Soil material including stone, wood chips, loess, and topsoil may be utilized as a vegetation-based material. This maximizes the efficiency of restoration work by allowing existing soil resources to be procured on site.

3. Selection of restoration materials and construction method

In the present invention, when it is judged that the suitability verification for the restoration target is appropriate, the restoration material can be selected later and the restoration method can be specifically set.

Particularly, in the step of selecting a restoration material and a construction method, a restoration target determined to be suitable in the conformity verification step is selected as a species to be introduced to the functional forest composition target site, Selecting a vegetation-based re-selection step for setting the vegetation-based material according to the soil environment at the functional forest formation site, setting the at least one of the vegetation-based re-installation type or the organic block- And a vegetation supplementary material selecting step of setting a vegetation supplementary material according to an inclined environment of the functional forest formation site.

This will ultimately determine the determination of artificial soil, vegetation-based material, supplementary material, seedling and seeds, port utilization method, and introduced species based on field survey results that match the functional forest site.

(1) Restoration Target Timing Determination Step

In particular, in the case of the restoration target, the completion period of the restoration of the functional forest is set to a long term, a medium term, and a short term, and thereby the introduced species are sorted and the seed crystals can be changed.

{Table 4: Selection method of plant application among restoration materials}

That is, as in the embodiment shown in Table 4, the restoration completion time can be divided into long term, middle term, and short term, so that the restoration species can be selected so that the species can be divided and planted based on the expected time.

In this embodiment, the species is classified into a first species and a second species by the growing season, and the first species can utilize the vegetation of three years or more, and the second species can utilize the vegetation of the first or second year.

Seedlings used for the first species or the second species may include cormorants, graves, graves and pot graves. In this case, the seedling is defined as a one-year-old seedlings after seeding, and the grafted seedlings are defined as seedlings transplanted with the seedlings. .

The use ratio of the first species and the second species is set differently, and the ratio of the tree species and the shrub species is set in the first species, so that the annual and annual ratios of the first species and the second species to be included in the total site can be set. Furthermore, in the case of seeds, it is also possible to set the blending ratio and amount according to the long-term, medium-term, and short-term. In Table 4, the first species and the second species were set based on an area of 10 m × 10 m, and the seeds were set to an area standard of 1 m × 1 m.

That is, the restoration target timing determining step divides the time for achieving the restoration target into three stages, that is, long term, middle term, and short term.

The composition ratio of the first species to the second species to be introduced into the functional forest formation site is set to a ratio of 2: 8 in the case of a long term, and the first species and the second species to be introduced into the functional forest formation target site, The composition ratio of species is set at a ratio of 4: 6, and in the case of a short term, the composition ratio of the first species and the second species to be introduced to the functional forest composition target site is set to a ratio of 6: 4 In the case of the present invention, the composition ratio between the first species and the second species is limited to the number of species).

This is because, as shown in Table 4, when the time for achieving the restoration goal is taken as long as 10 years or more, the ratio between the first species and the second species can be set to 2: 8 or 20% and 80%. For the first species, four trees are introduced at the same rate for tree species and shrubs over three years, and for the second species, 16 trees can be introduced by eight trees for shrubs and shrubs. In the case of seeds, it is possible to constitute the seeds and shrubs in a ratio of 3: 7 in a ratio of 3: 7 (seed ratio in the present invention is based on the weight of the seeds).

In addition, if the time to achieve the restoration goal is set to 4 to 10 years, the proportion of the first growing species will be increased, and the ratio of the first species to the second species will be 4: 6 or 40% and 60 %, And the ratio of the first species to the ratio of the tree to the shrub is set to 3: 5, so that the tree can be structured as 4 ~ 5 trees and 7 ~ 8 trees. In the case of the second species, the ratio of the tree to the shrub is 1: 2 so that it can be composed of 6 trees and 12 shrubs. In this case, the ratio of the first species to the second species is limited to the number of species.

In the case of short-term completion of the restoration target, the completion of the forest for restoration implementation should be implemented more rapidly, so that the proportion of the first growing species can be increased. And the ratio of the second species to the ratio of 6: 4 or 60% and 40%. In accordance therewith, the ratio of the first species itself is 2: 4 (20%: 40%), and in the second species itself, the ratio of arborea to shrub is 1: 3. In this case, the ratio of the first species to the second species is limited to the number of species.

According to the restoration period of the organ and medium-term, seeds can be contained at a ratio of 3: 2: 1, and when the organ is required, the seeds can be sufficiently grown, To be able to catch. The percentage of seeds is limited to weight.

(2) Selection step of vegetation-based materials

Table 5 illustrates the setting of the vegetation-based material according to the soil-based environment obtained through site surveys. The organic block shown in Table 5 is a plate-shaped mixed soil material mixed with seeds and organic materials, and means a structure that can be applied to the functional forests in the form of thrown or buried.

{Table 5_ Composition of vegetation-based materials according to soil and organic content standards}

(위 표 5의 유기물 함량 %는, 대상지의 채취 토양의 전체 부피 내에 포함되는 유기물이 차지하는 부피의 비율을 의미한다.)

(The organic matter content in Table 5 above means the ratio of the volume of the organic matter contained in the total volume of the soil collected on the site.)

That is, the selection step of the vegetation-based material is classified into the A, B and C type structures according to the soil depth and the organic matter content in the functional forest formation site. In the case of the organic matter content, Based on the volume of the organic matter contained in the extracted soil based on the volume of the soil of one soil, based on the total volume of the soil collected, Is classified as type B when the content is 3 to 5%, and type C when the content of organic matter is not more than 3%. The vegetation based material in A type with soil depth of 60 cm or more is B type vegetation with 10 to 60 cm of soil depth and 10 to 30: 40 to 5: 5 ratio of topsoil: loess: wood?: Peat moss: fertilizer The C type vegetation based material, which is based on the topsoil: loess: wood: peat moss: fertilizer ratio of 15: 25: 40: 5: 10 and the depth of the soil is 10 cm or less, topsoil: loess: wood?: Peat moss : The ratio of fertilizer should be 10: 30: 40: 10: 10. In the present invention, the mixing ratio of the vegetation-based material is limited to the volume ratio of each material based on the volume of the entire vegetation-based material.

That is, the soil condition is judged to be good (A) when the soil depth is 60 cm or more and the organic matter content is 5% or more, and when the soil depth is 10 cm or less and the organic matter content is less than 3% (C) can be done.

Therefore, in case of Type A and Type B, it is possible to construct using vegetation-based material, or throwing or embedding organic blocks into a target site. However, in case of Type C, the soil is too weak, And a construction cost is excessively charged. It is preferable to additionally include an additional base layer in addition to the vegetation base material.

Thus, in the C type soil, it is possible to further implement a base layer on the lower part where the vegetation base material and the organic block are disposed. This base layer is composed of the grains (15-20): loess (15-20): Masato To 65% by weight) and the silicate (15% by weight), so that the soil structure as a growth base can be improved. The mixing ratio of the base layer is also limited to the volume ratio of the constituent materials to be mixed on the basis of the volume of the entire base layer.

The organic block in Table 5 was set based on application of 9 (10 cm × 10 cm) per 1 m ² . In the case of the organic block, the structure and application method will be described below with reference to FIG.

(3) Method of reapplication based on vegetation and step of selecting vegetable auxiliary material

The method of applying the vegetation-based ash can be selected by installing the vegetation-based material when the equipment for planting the vegetation-based material can be entered. However, when the equipment enters the equipments such as the mountainous region or the valley region where the trees are concentrated, In this difficult place, the application method that allows the vegetation-based material to be constructed by throwing the vegetation organic block is selected. Of course, the organic block of the present invention may be implemented in parallel for stable growth even if equipment is allowed to enter.

In the selection step of the vegetation-based reapplication method, the vegetation-based material is installed or the organic block is selected according to the equipment input. In case of the type A according to the state of the soil mentioned in the above-mentioned Table 5, The thickness of the organic block is 2 cm in the case of the organic block arrangement, the thickness of the organic block in the case of the B type is 5 to 7 cm in the case of the B type, the thickness of the organic block is 4 cm in the case of the organic block arrangement, It is possible to realize the installation of ashes by 10cm and the thickness of the organic block by 6cm when the organic block is arranged.

Also, as shown in Table 6 below, select the growth auxiliary material to be fed into the functional forest formation site, and apply a net or mulching material at a level of 0 to 3 degrees in inclination, At least one of mulching material, net, and moisturizing material is selectively applied in the paper, and net and moisturizing material can be applied in a steep slope having an inclination of 15 degrees or more.

In addition, the vegetation organic block is embodied in the steep slope using the construction material of mulching material, net, and moisturizing material according to the slope, and the net and the moisturizing material are actively introduced. In the mucilage ground, mulching material, net, In the case of flat land, mulching material is applied positively and net and moisturizing material can be selectively applied.

That is, in the case of applying the organic block in the construction step, the structure in which the seed, vegetation-based material and growth auxiliary material are embodied as block-shaped organic blocks is disposed on the functional forest formation site in accordance with the degree of slope, It is possible to implement the structure in which the organic block is disposed on the surface of the soil in the mild slope and the organic block in the slope and the slope in a buried structure in the soil.

{Table 6_ Whether to use growth auxiliary materials according to the slopes of restoration sites}

For growth auxiliary materials, mulching material can be applied to chips (3 ~ 10cm size green chip), net for coir nets, and moisturizing material for moisturizing material (SUPER ABSORBENT POLYMER).

4. Construction phase

4 to 6 are diagrams for explaining a restoration method in a functional forest constructed according to the present invention.

That is, after the stomach growth supplement is selected, an organic block on which a moisturizing material is formed is placed on the lower surface of the flat surface, and a net or a mulching material is placed thereon to fix the stomach, A net or a mulching material is disposed on the lower surface of the organic block, and a chip breaking chip is applied and fixed. In the steep sloping paper, an organic block having a moisturizing material formed on the lower surface thereof is buried in the soil A net or a mulching material is placed on the net, and then a chip breaking chip is applied and fixed.

Specifically, FIG. 4 shows a process of applying the present invention to a gentle slope having a slope of 4 to 14 degrees or less. The organic block 100 on which the moisturizing material 20 is formed is placed on the surface 10 , A net 30 is laid on the net 30 and a broken chip is applied on the net 30 as a growth supporting material. In addition, a net fixing pin 50 may be applied to some elements of the object to be fixed.

5 shows an example in which the organic block 100 is placed on the target surface 10 (surface disposition type) when the inclination of the surface 10 of the functional forest composition target has an inclination of 0 to 3 degrees, A moisturizing material is applied to the lower surface of the object, that is, the portion in contact with the surface of the object.

In this case, the chip breaking chip may not be used, and a method of fixing the organic block using only the net by using the mulching material may be implemented.

Fig. 6 shows a structure for arranging the vegetation organic block for realizing the restoration target on the steep slope having an inclination of 15 degrees or more. In order to solve the problem that the slope of the organic block 100 is lowered due to the inclination of the slope, the slope of the slope can be realized by embedding an organic block in the soil (buried installation type) . That is, the organic block 100 is disposed on the target surface 10 in a buried form, and the moisturizing material 20 is coated on the lower surface of the organic block 100. Thereafter, the net is disposed thereon, the chip breaking chips 40 are applied to the net, and then the net is fixed with the net fixing pin.

The organic block applied in the present invention can be implemented as a plate-like block structure as shown in FIG.

Specifically, the organic block in the present invention is a mixed soil in which a mixture ratio of loess: (a mixture of fecal soil + crushed chips of wood chips + paper sludge) is 1: 1, and a mixture of CMC (carboxymethyl cellulose) -Block type structure composed of an adhesive material mixed with an acrylic polymer resin in a range of 20 ml to 50 ml, and a mixture of woody or herbaceous seeds.

Specifically, the organic block 100 has a first surface G1 and a second surface G2 facing the first surface G1, and the top surface of the first surface G1 and the second surface G2, And a plate-like body 110 having a thickness T of 2 cm to 6 cm on the lowermost surface of the surface can be obtained. Further, the thickness of the organic block may vary depending on the soil depth of the soil, as described in Table 4. When the soil depth is 60 cm or more, the thickness of the organic block may be 2 cm, . The thickness of the organic block is 4cm for 10cm ~ 60cm and 6cm for 10cm or less.

The plate-shaped body 110 of the organic block may be embodied as a mixed soil comprising loess, which is the main material, and a mixture of adhesive material, woody or herbal seeds, the material of which includes cellulose. That is, in the organic block according to the embodiment of the present invention, by simply compressing and molding the seed-containing material for regeneration of vegetation into the inside of the body and throwing it on the damaged restoration subject, the block easily breaks due to natural rainfall So that the seeds can be germinated and grown therein. Therefore, the organic block according to the embodiment of the present invention can be easily installed in a place where mechanical construction is difficult, that is, in a construction difficult to install vegetation using mechanical equipment, and a structure capable of self-growth through corrosion The branch is characterized by the vegetation block structure. Therefore, the organic block according to the embodiment of the present invention can easily be installed through throwing, while containing organic matter components that can easily increase corrosion resistance and increase germination of the seed, and can be easily broken by natural rainfall It is preferable to be able to be implemented with a structure having

To this end, the organic block according to the embodiment of the present invention may have a plate-like structure that is easy to break as shown in FIG. Furthermore, in general, germination of woody or herbaceous seeds is within 1 cm to 3 cm of the surface of the earth, and the germination rate is the best. Therefore, the organic block according to the embodiment of the present invention has a plate-like structure that is easy to break, and its thickness can be adjusted within a range of 2 to 6 cm, and can be realized as 1 cm to 3 cm. 1 (a), when the organic block according to the embodiment of the present invention is disposed on a restoration site by throwing or installing, the organic block may include rainfall that can accommodate natural rainfall for a predetermined period It is preferable that the receiving groove patterns 110 to 118 are provided.

The rainfall receiving groove patterns 110, 112, 114, and 116 may include at least one structure having a depth in the depth direction of the body on the first surface or the second surface. Particularly, it is preferable that the rainfall-receiving groove pattern is realized as a groove structure which does not penetrate the body, so that water is accumulated in the body for a predetermined period so that the present vegetation block can be easily broken. Particularly, in order to maximize easiness of cracking and corrosion, the organic block according to the embodiment of the present invention has a structure in which a plurality of rainfall receiving groove patterns are formed on the basis of the center point P of the body, as shown in FIG. 1 (a) It can be realized to have a deeper groove in the direction (X1, X3 - > X2) of the center point P. This is to realize the advantage that water can be concentrated at the central part and become easily broken at the central part when the water due to the rainfall becomes high on the surface of the plate-like body of the present embodiment. 7 (b), the organic block according to the embodiment of the present invention may be provided with a plurality of rainfall accommodating units (not shown) on the basis of the center point P of the body, The groove patterns 122 to 128 can be formed in a radial structure. In this structure, the structure of the groove can be realized so that the depth of the rainfall receiving groove pattern can be deepened as the distance from the end Y1 to the center P is increased. In this case, as described above, when the water due to the rainfall becomes high on the surface of the plate-like body, the water is concentrated to the central portion and becomes high, so that breakage can easily occur at the center portion.

In addition, in the structure of another embodiment of the present invention, as shown in FIG. 7C, the rainfall-receiving groove pattern 135 may be realized as a wide groove structure having a constant volume. Of course, in this case as well, the structure can be realized such that the depth of the central portion P of the plate-shaped body 130 increases. This also allows rainwater to be easily accommodated, and it is intended to increase the efficiency of breakage along with the probability of being accumulated for a certain period of time. In the embodiment of the present invention, the above-described rainfall-receiving groove pattern can be formed on both the first surface and the second surface, which is very useful in terms of convenience in construction. That is, when the construction is implemented as a throwing operation, the rainfall acceptance groove pattern is implemented on either side, and the construction is completed by the throwing operation without having to check the reversing operation again as a separate operation.

FIG. 8 is a conceptual diagram for explaining the characteristics of the defective site through the site survey of the functional forest formation site A according to the present invention, and restoring it by applying the heading, the second species, and the above-mentioned organic block .

The organic block 100 is a structure containing seeds therein, and it can be disposed on a target surface between a structure in which a tree, a shrub, and a glue are arranged.

FIG. 9 shows an example of modeling of an existing forest as a functional forest by implementing the above-described climate change impact mitigation forest as an example of the present invention.

Referring to FIG. 9, when (a) a forest formed from a basic oak tree community is set as a functional forest site, a preliminary investigation is performed to grasp the low vegetation of the present site, The structure of the deflection transition was identified, and it was identified that the point was damaged at some points.

(b), 33.5% of the total species were identified as the omnivorous species of oaks, and the need for forests with environmental buffers was raised as part of the urban development project. It is set up to create a shock-mitigating forest. In the case of planting, the method for improving the growth of vegetation according to the method of the present invention described below is applied. In the case of planting, Respectively.

After (c), the functional forest area was modeled as a multi-layered mixed forest developed as a functional forest capable of buffering the impact on climate change.

Hereinafter, various introducible plants that can be applied to the composition of the functional forest as restoration targets explained in the embodiment of the present invention will be described in more detail.

(1) Forests to respond to climate change

As a restoration target of the present invention, it is possible to implement a carbon-abatement forest as one of the forests responding to climate change. This can be achieved by adding species to be introduced when the species having excellent carbon accumulation function is over 30% at the functional forest formation site.

The species that can be introduced into the carbon abatement forests may include at least one species selected from the group consisting of acanthopanax, zelkova, oak, camphor, gambia, jade, jade, flower gardenia and azalea.

In addition, as one of the forests responding to climate change, in the case of mitigating climate change impact forests, the southern region is more than 30% of 2 species of tree species appearing in the range of 90 to less than 110 on the basis of the GW index as shown in Table 2 , Central region can be set as a target when more than two species of tree species appearing in the range of 70 to 90 are above 30%.

In this case, the species that can be introduced in the southern region are the oak tree, the crow tree, the chestnut tree, the dwarf tree, the camellia tree, the stamina tree, the mountain tree, the mountain mulberry tree, the oak tree, And can include one or more selected from the group consisting of camellia, camphor tree, charcoal tree, Huangchu tree, gum tree, and fur noodle. In the central region, It may include one or more selected from bamboo flower, true tree, mountain mulberry, oak, pine, oak, camellia, shavings, and magpie.

In addition to this, there are two kinds of trees that can be planted simultaneously in the two areas: spruce trees, weighted trees, spruce trees, spruce trees, dog cherry trees, dogwood trees, Tree, mulberry tree, mulberry tree, mulberry tree, mulberry tree, mulberry tree, mulberry tree, mulberry tree, mulberry tree, mulberry tree, mulberry tree The main tree, the urea tree, the mountain cherry tree, the hibiscus tree, the pine tree, the pine tree, the sosa tree, the pine tree, the mushroom tree, the minke tree, the mushroom tree, It is also applicable to trees, dogwood trees, Sorbus trees, caterpillars, width trees, fuzzy trees, bark trees, bamboo trees, hornbeam trees, pine trees, corn oil,

(2) Air Pollution Mitigation Forest

In the present invention, the above-mentioned air pollution abatement forest is characterized in that at least two kinds of species occupying the functional forest formation target occupy 20% or more of the density of the total species, It can be implemented as a fine dust reduction forest which can be realized when two or more kinds of species occupy more than 20% of the density of the whole species, and it is possible to implement them as a single or plural species in a target site.

Preventing Air Pollution The species that can be introduced into forests are birch, maple, pine, pine, ginseng, weighted trees, and oak trees. Species that can be introduced into the fine dust reduction forest are pellets, , An alder tree, a spruce tree, an elder tree, and an oak tree.

{Table 7_ SO ₂ absorption by species}

{Table 8_ can type O ₃ absorption}

{Table 9_ Absorption amount of NO _{2 by} species}

All species listed in Table 7, Table 8, and Table 9 above can be applied to the air pollution abatement forest of the present invention.

Hereinafter, the species that can be introduced into the fine dust reduction forest by the detailed function of the air pollution abatement forest of the present invention will be described.

{Table 10 - Comparison of absorbing capacity of air pollutants by type of planting species}

The effect of pollutant abatement is different for each species, and the deciduous forest has about three times higher absorption than the coniferous forest.

In cities, pollutants such as sulfur oxides and nitrogen oxides released from automobiles are very serious compared to the outskirts of cities. In the process of absorbing air through the leaves, the tree adsorbs pollutants in the air, which is a function of cleansing the polluted city. In addition, excessively abundant atmospheric carbon dioxide causes the earth to become the same as the greenhouse, causing an abnormal climate phenomenon where the atmospheric temperature rises. This is also absorbed in the process of absorption of the tree, thus playing a major role in preventing global warming. Carbon dioxide removal from the forest, oxygen supply, and the photosynthetic action of the greenery, carbon dioxide gas in the atmosphere and water absorbed from the roots chemically react with the organism to synthesize and fix the organic matter and simultaneously release oxygen to the atmosphere. Dust that floats in the air is adsorbed on leaves, stems and branches until it falls to the surface or is washed down to purify the surrounding air.

Comparing dust concentrations in forests and dust concentrations in other areas, dust concentrations in the factory area are 250 to 1,000 times higher than forests, and dust concentrations in large cities are 50 to 200 times higher. In large cities, there is a difference in the dust concentration between the center of the city and the outskirts of the city. Depending on the structure of the plant group, the effect of adsorption of dust is also different. Forests, shrubs, lawns, and farmland have the greatest effect of dust adsorption. As shown in the table below, the adsorption efficiency of dust by each species is classified as follows. As shown in the table below, pellets, hawthorn trees, hazelnut trees and the like have high adsorption ability of dust, and oak, beech trees are medium, , And the willow and aspen trees are very low.

{Table 11_ Adsorption capacity of dust by species}

In order to improve the efficiency of the fine dust-reducing forest of the present invention, it is desirable to form a multi-layered structure of water species and intermediate species having high dust adsorption ability so as to mitigate air pollution by alleviating a sudden impact on forest environment change Do.

(3) Forests to prevent forest disasters

In the present invention, when restoration forests for forest disaster prevention are aimed at, the functional forest area is located in the valley part, and at least one of the native vegetation occupies more than 50% of the total species, , It can be implemented as a forest preventing disaster prevention which can be realized when at least one species of the example species of the functional forest formation target area grows in the form of a band.

Species that can be introduced into Suwon forest include at least one species selected from oak, oak, and birch, or species that can be introduced into forests for prevention of mountain disaster are oak, camellia, aralia, , Ginkgo biloba, japanese tree, and bamboo tree can be included.

(4) forests promoting biodiversity

In the present invention, diversity-promoting forests for promoting biodiversity can be set as restoration targets. In this case, the diversity-promoting forest is a biodiversity-enhancing forest applicable to the case where the vegetation of the surrounding forest of the functional forest formation site has a multi-layer structure, or the surrounding forest of the functional forest formation site is a vegetation- Which is applicable to the case where the content of lime in the soil of the forest and the soil of the functional forest composition is 50% or more based on the unit area, which can be implemented when the plant is composed of 30% or more of the total density, .

Promoting biodiversity In forests, structural diversity of forests should be maintained to promote biodiversity.

In general, in urban forests, residential areas or farmland are often located nearby. In order to protect such important habitats on the scale of the forest, it is necessary to divide the use area of the residents, For the formation of multi-layered structure, it is necessary to consider planting of shrubs and shrubs as well as trees.

 Promoting biodiversity The species that can be introduced into the forest are at least one species selected from the group consisting of oak, oak, oak, oak, bole, azalea, hawthorn, jasmine, sphinx, .

Promoting Landscape Diversity Species that can be introduced into the forests may include at least one species selected from birch, maple, plum tree, maple, cherry tree, azalea and azalea.

Further, the limestone mine recovery forest can utilize the soil material including the limestone, wood chips, loess, and topsoil generated from the above-mentioned functional forests as a vegetation-based material. This species can be applied as a species for restoration, such as pine trees, pine trees, pine trees, mung bean, mung bean, oyster mung bean, oak oak, and mongolian tree.

In the foregoing detailed description of the present invention, specific examples have been described. However, various modifications are possible within the scope of the present invention. The technical idea of the present invention should not be limited to the embodiments of the present invention but should be determined by the equivalents of the claims and the claims.

110, 120, 130: a plate-like body
112, 114, 116, 118: Rainfall receiving groove pattern
122, 124, 126, 128: Rainfall receiving groove pattern
P: Plate-shaped body center
G1: First side
G2: Second side

Claims (26)

A restoration goal setting step of setting a model of the set target function forest for the functional forest formation target site; A suitability verification step of verifying suitability of a restoration target through on-site investigation of the target site set as the set restoration target; Selecting the restoration material and construction method to determine the functional forest model after the suitability verification and selecting the restoration material; And a construction step of constructing a functional forest model corresponding to a predetermined restoration target for the target site,
The restoration target setting step includes setting the restoration target to include at least one of the major target forest major classes including the climate change response forest, the air pollution reduction forest, the forest disaster prevention forest, and the diversity promotion forest ,
The conformity verification step is a step of identifying the species and the topographic information including the surrounding vegetation, the soil environment, and the slope of the functional forest composition target area and verifying the suitability of the restoration target set through the preliminary examination of the functional forest composition target area ,
The restoration material and method selection step may include:
A restoration target time determining step of selecting a species to be introduced to the functional forest formation target site and selecting a water species application method for the restoration target determined to be suitable in the conformity verification step; Selecting a vegetation-based material for setting the vegetation-based material according to the soil environment at the functional forest formation site; Selecting a vegetation-based reapplication method for setting at least one of a vegetation-based re-installation type or an organic block input type depending on whether the construction equipment can be input; And a vegetation supplementary material selection step of setting a vegetation supplementary material in accordance with an inclined environment of the functional forest formation site,
The restoration target timing determination step may be configured to classify the achievement timing of the restoration target into three stages of long term, middle term, and short term, and the composition ratios of the first species and the second species are set as a ratio based on the quantity of input species , The composition ratio of the first species to the second species to be introduced into the functional forest formation target site is set to a ratio of 2: 8 in the case of the long term, and the first species species to be introduced into the functional forest formation target site The composition ratio of two species is set to a ratio of 4: 6, and in the case of a short term, a composition ratio of the first species to the second species to be introduced into the functional forest composition target is set to a ratio of 6: 4,
The selection of the vegetation-based material is performed by limiting the mixing ratio of the vegetation-based material to the volume ratio of each material based on the volume of the entire vegetation-based material, B, and C type structures. In the case of the organic matter content, based on the volume of the organic matter contained in the collected soil based on the volume of the soil of the collected soil, based on the total volume of the collected soil Type A is classified as Type A when the containing volume of the organic substance is 5% or more, Type B when the containing volume of the organic substance is 3 to 5%, and C type when the containing volume of the organic substance is less than 3% The vegetation-based material of B type, which is implemented with a ratio of 10: 30: 40: 5: 5, and the soil depth is 10 to 60 cm, is topsoil: loess: wood ?: Peat moss: fertilizer C type vegetation based material with a ratio of 15: 25: 40: 5: 10 and a soil depth of 10 cm or less is 10: 30: 40: 10: 10 in the ratio of the topsoil: loess: wood?: Peat moss: fertilizer , And < RTI ID =
In the step of selecting the vegetation-based reapplication method, the vegetation-based material is installed or the organic block is disposed according to whether the equipment is input. In case of the A type, the vegetation-based material is installed at 1 to 3 cm, The thickness of the organic block is 4 cm for the organic block arrangement, the placement of the vegetation-based material is 10 cm for the type B, and the organic block for the organic block arrangement is 2 cm for the B type, 5 to 7 cm for the vegetation- The thickness of which is 6 cm,
The vegetation supplementary material selection step may include selecting a growth supplement to be input to the functional forest formation target site,
At least one of the net and the moisturizing material is selectively applied by applying a mulching material or applying a mulching material at a level of 0 to 3 degrees in inclination. In the case of a mulching material having an inclination of less than 4 to 14 degrees, , Net, and moisturizing material, and applying a net and a moisturizing material to the steep slope having an inclination of 15 degrees or more,
Functional forest composition method with various functions.
delete delete delete delete The method according to claim 1,
The restoration target timing determination step may include:
In the case of the seed to be introduced into the functional forest formation site, the input ratio of the tree and the shrub is set to 3: 7,
Long-term: medium-term: a weight ratio of seeds to be fed in the short-term is 3: 2: 1,
Functional forest composition method with various functions.
(In this case, the weight ratio of seed is defined as the ratio based on the weight of the seed to be fed.)
delete delete The method according to claim 1,
In the case of the C type,
Further comprising a base layer underneath the arrangement of the vegetation-based redistribution or organic block,
Wherein the base layer is a mixture of gypsum (15-20): loess (15-20): masato (55-65): silicate (15)
Functional forest composition method with various functions.
(In this case, the mixing ratio of the materials constituting the base layer is defined as the ratio of the volume of the constituent material based on the volume of the entire base layer.)
delete The method according to claim 1,
When the organic block is applied in the construction step,
Seed, vegetation-based material, and growth auxiliary material in a block-shaped organic block,
Wherein the functional forest is disposed in accordance with the degree of inclination,
And the organic block is disposed on the soil surface in the flat or the mild slope paper,
And the organic block is disposed in a soil-buried structure in the steep sloped ground,
Functional forest composition method with various functions.
The method of claim 11,
Wherein the organic block comprises:
Mixed soil in which the mixing ratio of loess: (fugitive soil + chip breaking chips + paper sludge) is realized at a volume ratio of 1: 1,
An adhesive material mixed with CMC (Carboxymethyl Cellulose) or a vinyl-acrylic polymer resin in an amount of 20 ml to 50 ml per liter of the mixed soil;
Which is composed of a mixture of woody or herbaceous seeds,
The plate-like block-
Functional forest composition method with various functions.
The method of claim 12,
In the construction step,
In the flat surface, an organic block having a moisturizing material formed thereon is disposed on the lower surface, and a net or a mulching material is disposed and fixed on the organic block.
In the above-mentioned gentle slope paper, an organic block having a moisturizing material formed thereon is disposed on a lower surface thereof, a net or a mulching material is placed on the organic block,
In the steep slope, an organic block having a moisturizing material formed on a lower surface thereof is disposed in a buried form in the soil, a net or a mulching material is disposed on the soil,
Functional forest composition method with various functions.
14. The method of claim 13,
The above-mentioned climate change-
Carbon abatement forests implemented when the share of the corresponding species of species classified on the basis of the carbon accumulation function is 30% or more of the total species species density; And
In the southern region, the southern region has more than 30 species of tree species with more than 30 species of tree species in the range of 90 to less than 110 species. Climate change impact mitigation forest implemented when more than two species of tree species are more than 30% of tree species density of whole species appearing;
/ RTI >
Functional forest composition method with various functions.
15. The method of claim 14,
The species that can be introduced into the carbon-
Which comprises at least one member selected from the group consisting of spiny myrtle, zelkova, oak, camphor, gambia,
Functional forest composition method with various functions.
15. The method of claim 14,
The species that can be introduced into the climate change impact mitigation forest include,
In the above southern region, there are many kinds of trees such as oak, oak, pine tree, camellia, camellia, quercus, mountain mulberry, oak, oak tree, And at least one selected from the group consisting of wood, wood, wood,
The above-mentioned central region is divided into three parts: oak oak, oak tree, conifer tree, camellia tree, ash tree, ash tree, bugae flower tree, true tree, mountain mulberry tree, oak tree, pine tree oak tree, Wherein at least one selected is included,
Functional forest composition method with various functions.
18. The method of claim 16,
The air pollution abatement forest,
An air pollution prevention forest implemented when two or more kinds of species occupying the functional forest formation target occupy 20% or more of the density of all species; And
A fine dust reduction forest which can be implemented when two or more kinds of species occupying the functional forest formation target occupy 20% or more of the density of all species;
≪ / RTI >
Functional forest composition method with various functions.
18. The method of claim 17,
The species that can be introduced into the above-
And at least one member selected from the group consisting of birch, maple, pine, pine, pine, weed,
Functional forest composition method with various functions.
18. The method of claim 17,
The species that can be introduced into the fine dust-
Which comprises at least one member selected from the group consisting of a pine tree, a hawthorn tree, a hazel tree, a pine tree, a duck tree, a pine tree, a pine tree,
Functional forest composition method with various functions.
15. The method of claim 14,
In the above forest preventing forest,
The forests where the functional forests are located in the valleys and at least one of the native vegetation occupies more than 50% of the total species and can be constructed in a multi-layered structure;
A forest preventing disaster prevention forest which can be realized when at least one kind of native species native to the functional forests is formed in a band shape;
And at least one of < RTI ID = 0.0 >
Functional forest composition method with various functions.
The method of claim 20,
As a species that can be introduced into the forest of the source forest,
At least one member selected from the group consisting of oak, oak, and birch is included as a main species, and further includes at least one species of Quercus mongolica and Pine as an assistant species.
Functional forest composition method with various functions.
The method of claim 20,
The species that can be introduced into the mountainous disaster prevention forest,
Which comprises at least one selected from the group consisting of oak, oak, camellia, aralia, oak, ginkgo, oak,
Functional forest composition method with various functions.
15. The method of claim 14,
The diversity-
A biodiversity promotion forest applicable to the case where the vegetation of the surrounding forest of the functional forest formation site has a multi-layer structure;
Forests promoting forest diversity that can be implemented when the surrounding forests of the functional forests are composed of more than 30% of the total density of the vegetation as the landscape species; And
A limestone mine recovery forest applied to a case where the lime content of the soil in the functional forest formation site is 10 to 50% or more based on a unit area;
And at least one of < RTI ID = 0.0 >
Functional forest composition method with various functions.
24. The method of claim 23,
The species that can be introduced into the biodiversity-
And at least one selected from the group consisting of oak, oak, oak, oak, bark, azalea, oak, hornblende,
Functional forest composition method with various functions.
24. The method of claim 23,
The species that can be introduced into the above-mentioned scenic diversity-
Which comprises at least one member selected from the group consisting of birch, alder tree, plum tree, maple, cherry tree, azalea,
Functional forest composition method with various functions.
24. The method of claim 23,
The limestone mine recovery forest,
The present invention relates to a method and apparatus for producing a functional forest using a soil material including a stone material, a wood chip, a loess soil,
Functional forest composition method with various functions.

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