KR200361416Y1 - Underwater structure for surfgrass transplantation - Google Patents

Abstract

The present invention relates to an underwater structure for implantation of horseshoe skin. More specifically, it is an underwater structure for transplanting horseshoe skin mainly distributed on the east coast of Korea as a marine plant different from algae, and on the surface of concrete or steel structure. A number of threaded protrusions are provided for easy fixation of the horseshoe-blooded graft bundle secured with a rubber strap. The uneven portion of the threaded protrusion prevents the algae from being pulled out by the algae, and the leaves and some vines move with the algae to mitigate the friction of the water, helping to avoid being swept away by the waves. And roots are attached to the aquatic structure to grow geodetic by forming a large horseshoe skin colony to provide a lot of fish feed, spawning ground and fry of the fry and contribute to the increase of coastal biodiversity and fishery productivity.

Description

Underwater structure for surfgrass transplantation

Unlike seaweeds such as seaweed and kelp, horseshoe blood is a kind of algae, a marine plant with true roots, stems, and leaves. It is inhabited by fast algae and waves, and is distributed mainly on the east coast in Korea.

Malzalpi roots are firmly fixed to rock or gravel, and extend to the basement to form geodes, grow and form a larger colony. It filters out fine particles, such as sand swept away by the waves, and setstles the basement tissue more firmly as it sinks around its basement and roots. In addition, various types of lugworms can be inhabited in the subterranean soft ground to provide food sources for sea crabs and fish, and to feed on microalgae and marine flora and fauna that are attached to the leaf or leaves of the horseshoe. Fish will flock around the colony. Various marine animals play an important role in coastal fisheries production because they are using breeding grounds or breeding grounds for fry to breed species safely from predators and strong waves.

In the natural state of horseshoe blooming, which has such important functions, mature seeds are usually swept away by waves or algae in the flowering state and attached to the rocks or gravel gaps and continue to grow, forming geodes. As it is a strong region, it is difficult to attach to rock or gravel cracks, and it takes a very long time to reach a growth stage that can generate geodesic, making it very difficult to form an algal colony.

In the past, artificially implanted horseshoe blood was not common, but in some cases, the horseshoe blood was tied with a string and hung on a stone to attempt transplantation. The transplant did not work. In addition, some tried to transplant the Alzheimer's circumferential tissue with the underwater glue to force the bedrock, but the toxicity of the chemicals interfered with the metabolism of the plant, which resulted in the death of the transplanted Alder. So far, there have been no examples of successful Malphal implants.

The present invention relates to an underwater structure for implanting a horseshoe skin that survives a strong wave and fast algae habitat. In detail, a number of threaded protrusions appear on the surface of concrete or steel structure, It can be easily fixed by inserting a bunch of horseshoe blood transplant seedlings. Thus transplanted horseshoe blood is not swept away by the foliar and leaf parts move along the flow of a strong wave or algae, the underground diameter and the roots are attached to the structure to grow and multiply to form a large horseshoe colony.

1 is a perspective view of an underwater structure for implantation of alveolus used in the present invention.

2 is a threaded protrusion embedded in the surface of the underwater structure used in the present invention.

3 is a schematic diagram of the horseshoe skin used in the present invention.

Figure 4 is a schematic diagram of a horseshoe-pied bundle tied with a rubber band used in the present invention.

Figure 5 is a state diagram implanted by using the present invention.

Hereinafter, described in detail by the accompanying drawings as follows. 1 is a perspective view of a structure 1 for implantation of a horseshoe, characterized in that a plurality of threaded protrusions 2 are shown, the shape is not limited to this figure. Drop it at the target point where you want to implant it. The diver inserts the horseshoe cork bundle 4, which is bundled with a plurality of horseshoe vines 9, with a rubber band 5, into the threaded protrusion 2. The uneven portion of the threaded protrusion 2 shown in FIG. (6) prevents the horseshoe grafted into the fast algae from being easily swept away, making the roots (7) and the basement (8) more firmly anchored to the structure, and the leaves (10) and some of the vinegar (9) parts By moving with it minimizes friction to help fix the implanted horseshoe bundle (4).

Figure 3 is a schematic diagram of horseshoe blood used in the present invention, horseshoe blood is a plant with true roots, stems, leaf tissues basement (8) and root (7) is a basement that is fixed to the floor, leaves 10 and vinegar (9) is divided into above-ground parts. 4 is a bundle of horseshoe blood transplant seedlings (4) tied with a rubber strap (5) used in the present invention, in detail, the bottom portion of the leaf vine (9) of a number of horseshoe skin is bundled with a rubber strap (5). 5 is a state implanted using the present invention to the horseshoe cortex bundle 4, the basement is fixed to the underwater structure (1), the ground portion grows and breeds in the water to form a wide horseshoe colony.

It is no exaggeration to say that Malzalphy's implantation in an environment where there are strong waves and fast algae has never been successful. Using this design to easily implant horseshoe blood, the implanted horseshoe blood can move with strong waves or algae to reduce friction, so that the underground parts fixed to the threaded protrusions are firmly fixed to the bottom of the structure. As it extends into the basement and grows as a geodetic tree, it forms a new wide horsesal blood colony. The formed algae colony is a direct and indirect food source for aquatic resource animals, providing fish habitats, spawning grounds, and breeding grounds for fry to enhance fisheries productivity. It will make you a rich sea.

Claims (1)

A structure made of reinforcing steel or concrete to be fixed to the bottom of the sea after the injection; A plurality of protrusions formed on a surface of the structure and having a plurality of bent portions; Inserted outside the concave-convex portion, horseshoe bunches tied with a leaf leaf of a plurality of horseshoe skin; Consist of An underwater structure for transplanting a horseshoe skin, characterized in that the implanted horse skin is fixed and seated on the structure to grow in the water.