KR20030052942A - Sod mat using plants belong to the family gramineae for waterfront and plant floating island restoration and process for production thereof - Google Patents

Abstract

PURPOSE: A sod mat using plants belong to the family Gramineae for waterfront and plant floating island restoration and a process for production thereof are provided to form the plant floating island in a short time by increasing the growth efficiency thereof. CONSTITUTION: In a method of forming a sod mat by nutritional-propagating the stem of grasses, a plant layer(10) formed with the stem or root of grasses is disposed between a nylon net(20) and a moisturizing material(30) to make a mat. The mat is prevented from being flaggy by using a reinforcing material(40). The mat floats on the surface of the water using a floating body(50) and a floating frame(60).

Description

Sod mat using plants belong to the family Gramineae for waterfront and plant floating island restoration and process for production

The present invention relates to a plant turf for restoring natural vegetation using rice plants, including reeds, and a composition method thereof. More specifically, the present invention relates to a reed turf, and a method for forming the same, which can increase vegetation coverage in a short time by manufacturing a reed turf using roots of stems and root nodes of reeds.

Recently, efforts and attempts to restore the natural environment destroyed by industrialization and urbanization are increasing day by day. Ecological restoration requires a new method based on ecological knowledge, not an engineering method based on existing civil and landscaping, and one of these methods is a planting method using a turf. Turf is developed from the method of planting grass and refers to a form that is produced in a carpet or mat form by using tangled phenomenon as the roots of plants grow. Turf is one of the vegetation restoration methods applied to various plant species because it has the advantages of convenience of transportation and early coverage of vegetation.

The above turf can also be applied to artificial plant islands, one of the methods of restoring vegetation. As an effective ecological technology that can be restored, it has been studied to have effects such as water purification, providing bio habitat, reducing waves, and creating scenic beauty. Plants planted on the plant island are mainly water plants such as reeds, babies, strings and yellow irises.

Among the purified plants, reeds ( Pragmites australis ) have been widely applied to the restoration of rivers, lakes and wetland ecosystems. Reed is one of the plants that thrives in rivers and lakes of Korea. It is a perennial herbaceous plant in the familyaceae. Reed, a water-based aquatic plant, is often used for vegetation restoration because of its high productivity and high pollutant purification ability. In general, the ecological restoration method using reeds was constructed by reeding, replanting, and cutting. However, the seeding method has low germination rate because no method of promoting germination has been identified. Difficult to apply

Conventional research on reed turf has been known in the Republic of Korea Patent Publication No. 1999-024077 regarding the production of reed turf turf for the rehabilitation of natural vegetation on the shores of urban rivers and the method of its composition, the Republic of Korea Publication No. 2000-0061137 BACKGROUND OF THE INVENTION Methods of making molded turf seedlings of reeds and moonroots have been known. However, the above method relates to a method for producing turf seedlings in which seedlings of reeds are seeded or cut into rhizomes, and then low-temperature pre-treatment, followed by cultivation in paddy fields or wet places for a certain period of time, and then standardizing the size, and transplanting them into waterside areas. It is low as 14 ~ 44%, and the development of root group of reeds is late, and even when cutting and cutting rhizome, it is possible to grow roots after planting for 5-6 months in rice paddy, so it can be transplanted. In terms of its use was limited.

The present invention is to solve the above problems, take the reed adapted to the local environment, and then make a turf with the stem and root portion, float the turf on the river or lake by using a float, etc. The present invention has been completed by shortening the time required for nutrition propagation and providing rapid vegetation restoration.

Accordingly, it is an object of the present invention to provide a plant turf using a rice plant, including reeds, and a method of forming the same.

Hereinafter, the configuration of the present invention will be described.

1 is a schematic diagram showing the reed ground (AG I, AGII) and the ground (BG I, BGII) divided to form a turf for each reed part.

2 is a cross-sectional view of a plant island located on the surface of water constructed using a reed turf.

Figure 3 is an example of the vegetation development in the vegetation island in two cases of the reed planting by the pot in the Gyeongpo lake and the reed planting around the lake.

4 is a view of the roots and stems developed in the ground and underground turf.

5 is a graph showing the number of stems of reeds developed in each experimental group (AG I, AGII, BG I, BGII).

Figure 6 is a photograph showing the appearance of the stem developed in each experimental (AG I, AGII, BG I, BGII).

7 is a schematic diagram of a reed turf constructed using a nutrient mixture soil.

Explanation of symbols on the main parts of the drawings

10: plant layer consisting of the stem or root of rice plants

20: nylon mesh 30: moisturizing material

40: reinforcement 50: floating body

60: floating mold 70: nutrient culture soil

80: fixed pack

In the present invention, in forming the turf, in order to measure the effect of turf formation according to the area of the reed, the length of the ground portion is about 100 cm (hereinafter abbreviated as 'AG I'), 1 to 2 stem nodes About 15cm to be included (hereinafter abbreviated as 'AGⅡ') Underground branch cut to about 100cm in length of branched underground diameter (hereinafter abbreviated as 'BG I') The turf was made from the basement cut to about 15 cm (hereinafter abbreviated as 'BGII') and the effect was compared. The length of the ground part was about 100 cm, that is, AG I was most preferable for forming the turf.

The present invention is characterized by forming a plant island by inducing a new stem from the stem or root portion after forming a turf to the stem or root portion of the rice plant.

Preferred embodiment of the present invention, after taking the grazing plant 10 adapted to the local environment so that the length of the ground portion is about 100cm between the nylon mesh 20 and the moisturizing material 30 to produce a mat and then reinforcement (40) to prevent the mat from sagging and float on the lake or river using the floating body (50) and floating frame (60) to complete the plant island construction, or if you can not float on the river or lake The moisturizing material, nutrient mixture soil, reeds, moisturizing materials in sequence to form a mat and then fixed with a fixed pack to form a reed turf.

The present invention is a turf produced by floating a plant on the water as a condition sufficient water in the surrounding environment, but it is important to maintain the proper level because the germination rate is significantly lowered when exposed to inundation or drying during vegetation germination. use. However, as vegetation roots develop, the function of the moisturizer is no longer required and must be decomposed naturally. Otherwise, over time, the weight of the plant islands increases, causing them to lose their center. Therefore, as a material of the moisturizing material is used is a material that is naturally decomposed as the plant root is developed while having excellent moisture retention, and preferably use a palm fiber mat, rice straw, greening rod and the like.

The reinforcing material is used to prevent sagging of vegetation mats, and it is preferable to process the material with a hole having a diameter of 3 cm or more so that the root of the plant is well lowered. For example, a plastic net is used.

The floating frame is used to protect plant islands when installed in places with poor environment, that is, where there are a lot of floating materials such as garbage, or where the wave or the flow rate is high. Examples thereof include PEM pipes. The floating body is installed to allow the plant islands to float in the water and can use artificial buoyancy materials.

The reinforcement, floating frame and floating body can be selected and used according to the size of the turf and the surrounding environment, and may be omitted in some cases.

The nutrient mixture soil is preferably mixed in a volume ratio of vermiculite: pitmos: powder for the reed growth in a volume ratio of 1: 1: 1, and laminated on the mat in a thickness of 5cm to 10cm. The blended soil facilitates root development of rice and plants, facilitates lubrication, and improves plant development with excellent drainage and water retention. Plant islands develop roots over time, and developed roots extend into the water to obtain nutrients from the water bodies. At this time, the soil is lost through the hole of the moisturizer formed by the root development. However, the soil support and nutrient supply are already replaced by the roots of already developed plants, and thus do not affect the growth of the plants. Rather, the increase in the weight of the plant islands caused by the growing plants is reduced to soil loss. Become a complementary relationship.

Plants used to create a turf in the present invention can be used for all kinds of plants belonging to the family (Gramineae), preferably Phragmites communis , Phragmites japonica , Phacelurus latifolius use.

Hereinafter, the present invention will be described in more detail with reference to Examples. These examples are only for illustrating the present invention in more detail, it will be apparent to those skilled in the art that the scope of the present invention is not limited to these examples.

Example 1 Preparation of Reed Turf and Observation of New Stalks

Step 1: Harvest Reeds

On July 5, 2001, reeds were grown to the roots of the natural wetlands of Research Eco-park of Asome, located in Jincheon-gun, Chungcheongbuk-do.

Stage 2: Classification of Reeds

The collected reeds were divided into the ground part and the ground part based on the flooded part. In particular, the flooded stems were considered underground and included in the basement.

Plant samples for reed turf formation were divided into four types, as shown in FIG. There are two types of reeds in the ground, which are about 100 cm long (above-ground I, AG I) and about 15 cm cut to contain 1-2 stems (above-ground II, AG II). Divided. Like the ground sample, the underground part was cut to about 15 cm to include the short-ground I (BG I) and 1-2 nodes cut to the length of 100 cm among the longest branches (below-ground II, BG). II).

Step 3: Preparation of Reed Spouts

Float was made to a size of 1 × 1 m ² using artificial buoyancy material having a floating, and prepared 1 × 2.1 m ² palm fiber mesh. Reed samples prepared with AG I, AG II, BG I, and BG II were placed between the nylon mesh and the palm fiber mesh (humidant), and were immersed with green tape to prevent loss of the reed samples.

The reed sample was not developed on the 5th of July when the experiment was started, and the reed sample placed on the floating body was constantly prepared such that the number of stems and root nodes was 220.

Fourth Step: Composition of Plant Island

The turf produced in the third step is placed on the floating body 50, as shown in Figures 2 and 3, using a reinforcement 40, a float 60 to form a plant island, Ache Co., Ltd. Jincheon-gun, Chungcheongbuk-do Research Eco-park floated in my pond.

Step 5: Observation of New Stem

Vegetation surveys measured the density and height of new stems at 0, 1, 4, 6, and 7 weeks after plant island installation. At week 7, the plant islands were decomposed to measure biomass and root length.

The biomass was measured after dividing the plant into the ground part and the underground part, and separating the underground part into the underground diameter and the root again. Aboveground biomass was measured by the weight of newly emerged stems on water. Underground biomass included all submerged parts except the ground part. The collected plant samples were dried in a 80 ° C. dryer to a constant weight and weighed to measure dry weight.

As a result, the foliage and roots began to appear simultaneously in AG I, a stem length of 100 cm, and AG II, a stem length of 15 cm. As shown in Table 1, the length of the foliage of AG I and AG II that emerged from the foliage after 49 days of installation was 70 cm and 35 cm, respectively, and 55 cm of BG I and BG II that appeared in the underground diameter. It was longer than 30 cm.

Length of stem developed in days (cm) Days passed Ground Underground AG I AG II BG I BG II 0 0 0 0 0 7 0 0 10 3 28 25 25 35 20 42 50 35 50 25 49 70 35 55 30

On the third day after the experiment, a new foliage appeared at the node of the basement I experimental zone (BG I) having a length of 100 cm (FIG. 4). The apical tip changes from white to red and develops into a new stem. Seven days after the start of the experiment, a new leaf part began to develop in the node of the short cut underground diameter (BG II) (Table 2). The appearance of foliage in the basement developed from the apical part of the basement to the node part.

% Of new stems developed over days Days passed Ground Underground AG I AG II BG I BG II 0 0 0 0 0 7 0 0 2 One 28 77 71 18 49 42 97 92 28 52 49 138 136 47 90

The number of new stems that appeared according to the number of days passed is shown in FIG. 5. Up to 7 days after installation, the foliage formation of the underground diameter was active, but after that, the foliage formation was much higher.

The characteristics of the new stems were clearly distinguished in the experimental zones of the ground and the underground. The stems produced in AG I and II were thin and evenly grown throughout the square spheres, but a large number of thick stems were produced in BG I and II. The variation in height was severe (FIG. 6).

The highest biomass after 7 weeks on plant islands was AG II with dry weight of 356 g and the least was 131 g as BG I (Table 3).

Biomass of stems, roots and underground diameter developed in above ground and underground (g) Days passed Ground Underground AG I AG II BG I BG II stem 65 32 25 20 Underground view 172 318 92 188 Root 13 6 15 68 Sum 250 356 132 276

The reed's ground / underground (S / R) biomass ratio was highest in AG I (Table 4). The dry weight of AG II and BG II which cut the ground part or the underground part to a certain size was high, but the ratio of the ground part / underground part (S / R) was as low as 0.1.

Ground / Underground Biomass Ratio (S / R) Days passed Ground Underground AG I AG II BG I BG II S / R 0.379 0.102 0.272 0.106

Example 2: Plant Island Composition in Gyeongpo Lake with Salinity 7-15%

Reeds can grow even in salinity ranges from 45-60 ‰ and are widely distributed geographically from coast to rivers. There are ecotypes of reeds that grow in various environments. The most significant environmental factor is salinity. As such, the ecological type of reeds is preferably used for restoring vegetation where the environmental factors are unusual.

The inventors of the present invention constructed reed plant islands in Gyeongpo Lake with a salinity of 7-15 ‰ by planting reed pot seedlings prepared in fresh water in 1998, but failed to restore vegetation. However, in 2001, the experiment was conducted to directly harvest and transplant reeds growing in the area. As a result, the coverage of the reeds reached 80-100%, indicating that the restoration using the local reeds was very effective (FIG. 3).

As in the above method, in the case of transplanting reeds growing in the field, cutting and inserting only the stem without harvesting the aeration including the underground part can prevent the destruction of the growth site.

Example 3: Preparation of Reed Soybean Paste Using Nutritious Soil

If it is not possible to float in rivers or lakes, nutrient turf is used to make reed turf.

First, as shown in FIG. 7, a plant layer consisting of a moisturizing material 30 stacked on a waterside part, a nutrient mixture soil 70 stacked on the moisturizing material, and a stem or root of rice plants stacked on the nutrient culture soil ( 10) and the moisturizing material (30) laminated on the plant layer to construct a reed turf. Compared to the reed turf fed only the water without nutrient mixture soil, the new stems of reeds were induced on the turf added with the mixed soil, and the growth rate was about 10 days faster.

Above, as is apparent from the above embodiment, the vegetation restoration method using the turf of the present invention as a method that can overcome the disadvantages caused by sowing and pot planting, nutritional propagation of stems of rice plants including reeds, growth efficiency is It is possible to form a plant island in a short time, and in particular, it is effective to form reed turf even in a lake with high salt, and it is an effective inventor for the environmental industry because it has an effect of promoting reed growth by using nutrient soil. will be.

Claims (3)

In the method of forming a plant turf, characterized in that to form a turf by nourishing the stems of rice plants, Plant layer (10) consisting of stems or roots of rice plants between the nylon mesh 20 and the moisturizing material 30 to make a mat and then using the reinforcement 40 to prevent the mat from sagging and floating ( 50) and the method of forming a plant turf, characterized in that floating on the water surface using a floating mold (60). In the method of forming a plant turf, characterized in that to form a turf by nourishing the stems of rice plants, Plant layer (10) consisting of the moisturizing material (30) laminated on the waterside part and the nutrient mixture soil (70) stacked on the moisturizing material, and the stem or root of rice plants laminated on the nutrient culture soil and laminated on the plant layer Composition method of the plant turf characterized in that the construction by fixing each corner portion of the mat consisting of a moisturizing material (30) with a fixing pack (80) The method of claim 1 or 2, wherein the plant is selected from the group of reeds, moon roots, moss moon.