KR100917790B1 - Grid type hollow block for ecological restoration of bank and construction method of bank using thereof - Google Patents

Abstract

A lattice-type hollow block for ecological restoration of bank and a construction method of bank using the same are provided to make mass production of bank block possible and to shorten the construction time of bank. A construction method of a bank using lattice-type hollow blocks for ecological restoration comprises the steps of forming a foundation(100) by cutting and organizing a bank slope, setting a water barrier(200) a mesh(300) on the foundation in sequence, arranging and connecting lattice-type hollow blocks(400) and fitting anchors(A) anchor coupling holes formed on horizontal frames and vertical members of the hollow blocks to be settled in in-situ ground(F), filling fillers(500) of gravel in the hollow of the blocks, forming a soil layer(600) of certain thickness in which plant seeds and leaf mould are mixed, placing a soil covering material(700) over the soil layer and setting a mesh(800), and settling the soil covering material and the mesh within the soil layer using a fixing pin(900).

Description

Grid type hollow block for ecological restoration of bank and construction method of bank using

The present invention relates to restoring the ecology of the banks in an environmentally friendly way when constructing or maintaining bank slopes, shores, shores, lakes, or swamps. Especially, the bank slopes are constructed of lattice-type hollow blocks united as factory products. This ensures the structural stability of the slope by maintaining the shape and integration of the bank's slopes, and ensures ecological restoration of slopes and waterfront spaces as well as eco-friendliness. The present invention relates to a lattice-type hollow block for ecological restoration of a levee, which can reduce the cost of construction and shorten the construction time, reduce the cost of construction and facilitate maintenance, and construct a levee using the same.

A dike is a civil structure that not only prevents flooding of rivers, coasts, lakes and swamps, but also builds up soil for plucking and irrigation, and builds water to protect the facilities outside the dike. It functions to prevent flooding by blocking it, and consists of various types of embankments such as rivers, coasts, reclaimed lands, and embankments.

These banks are generally composed of front slopes (lower and upper), front barriers, slope shoulders, rear barriers, rear slopes (lower and upper sides), and drainage channels. Although it is made up, it is constructed in the structure of various forms of the mixing type which has an upright part in the upright type | mold of a concrete tank, and an inclined type | mold.

In general, levees fill the ground with soil, or pile it up with soil, and build the surface with grass, stone, concrete, etc., to prevent erosion by flow velocity, to settle green plants, and to restore ecology and water. For the waterfront space, the construction type is divided into various construction methods depending on the place and purpose.

It is preferable that the base ground, which is the foundation floor of the slope, has a large bearing capacity, but the ground of the waterfront area such as rivers is not so good, so the ground improvement work should be carried out at important points, and the design suitable for the ground or the dike to avoid weak ground should be planned. In addition, it is necessary to build a bank-like structure for smoothly joining both of the two main streams at the confluence point of the main stream and the branch, which causes a bad result such as sediment deposition.

In addition, it is ideal for the soil to be laid on the dike to have a large stability slope and an impermeability when submerged in water. Particularly, the soil is coated to prevent the loss of soil to be deposited on the surface of the dike. May be overlaid with concrete.

On the other hand, there are various types of bank slope construction methods for stabilizing bank structures in civil works such as river banks, lake banks, coastal banks, bank building, and river maintenance.

First, as a construction method using a concrete structure, a concrete block method for stacking concrete blocks on the slope, a concrete block method coated with grass inside the concrete block of the slope, and a construction method using stones, There is a stone attaching method for laminating stones and combining mortars, and a natural stone stacking method for laminating stones on a corresponding slope.

Among the dike slope construction methods, the stone attaching method, concrete block method, natural stone stacking method, etc. are very demanding and cumbersome, which increases the construction cost, prolongs the construction period, and damages the natural landscape around the construction site. have.

In order to solve the above problems, in recent years, various technologies have been created and introduced by eco-friendly greening methods in connection with the construction of the bank slope. That is, the planting method using the gabion gabion is installed on the slope, sowing plant seeding and greening is adopted and widely used.

The greening method is known to have advantages such as relatively simple and easy work process, low construction cost, short construction period, and harmony with the natural landscape around the construction after construction.

That is, in most cases, in the greening process in the form of surface exposure of the reticular structure by monotonous gabion gabion, plant seeds are planted on the slope, and then the plant seeds are made of reticulated bodies made of natural fibers on the slope. It is covered with a geonet to prevent the loss of soil and plant seeds.

However, these geonets not only penetrate freely through sparsely woven eyelids, and there is a possibility that soil or plant seeds may be lost, and in fact, vegetation and vegetation may not be promoted because plant seeds are exposed to their natural state. It had serious consequences for achieving its original purpose.

In addition, tree branches, trash, etc. floated from the upstream during the flood is caught in the eyes and messed out in appearance and requires a cumbersome maintenance that must be separated and removed.

As a related art in this regard, Korean Patent Publication No. 10-0802197 (Registration Date: 2008. 01.31) is known.

This prior art has a flexible Gabion wire mesh (1), a plurality of concrete blocks (2) connected to each other in the front and rear direction around the Gabion wire mesh (1), and the space portion (3) between the concrete blocks It is formed so that reinforcement soil is sprinkled from the outside into the space so that vegetation is vegetated.

This technology has the advantage that the operator can quickly assemble and install in the field, and the vegetation soil is put into the space between the concrete blocks, thereby reducing the construction cost by not using the filling material such as crushed stone. As the surface exposure type of structure, it is not easy to transport because many concrete blocks are connected, and there is a limit to vegetation due to the outflow of soil between blocks after installation, and it is disadvantageous to maintain the shape of the network when heavy rains occur. There is a problem that, and the garbage that is floating from the upstream is caught in the reticular body itself, there is a problem that looks aesthetically unsightly.

As another prior art, domestic registered utility model publication No. 20-0419169 (June 16, 2006) is known.

This other prior art constitutes a wall surface in which the inner surface of the skeleton of the rectangular planar structure is formed of the net body 4, and the inside of the frame of the hexagonal structure in which the skeleton of the wall surface is in contact with the spiral fastener 5 is assembled. On the side, a gabion revetment is provided with a vegetable porous structure (6) surrounding the inner side, an amorphous stone structure (7) inside, and a vegetation roll (8) on the upper side. It is.

This technique is advantageous in that the vegetation roll 8 is used to prevent the detachment of the plant by running water until the slidability of the plant at the tip of the stone structure 7 is stabilized. The surface exposed type of the reticular structure, which is not exposed to the soil itself due to rain after installation, and the trash floating upstream when heavy rain falls on the net itself, resulting in unsightly appearance. There is a problem in that it is disadvantageous to maintain the shape of the mesh and the structure, the stone purchase and installation cost of the stone for installation in the form of stone structure, there is a problem extending the construction period.

Such prior arts are made of reticulated bodies, and due to the structure and exposure form of the reticulated bodies, there is a possibility that rainwater freely penetrates through sparsely woven mesh eyes and thus the soil or plant seeds may be lost. It is a fundamental problem in the realization of greening of natural slopes due to poor growth environment.

In addition, after putting the stone in the mesh during the operation of the gabion gabion, there is a problem that there is a concern of safety accidents, such as an increase in the installation time according to the constant shape maintenance work of the network and the resulting increase in cost and injury of the worker.

In other words, manpower is required due to the type of work to store stones in the geonet, which is a mesh network, and to bind the mesh in the field (maintaining and binding of the shape, transportation by equipment, adjustment of the installation position, connection between the gabions, etc.). And as an inefficient operation form, such as an increase in the installation period, there is a problem that the equipment required to install it must be provided separately.

In addition, after storing the stones in the mesh, it is not only inconvenient to handle and install due to the on-site work form to distinguish between the front and back according to the shape maintenance, and also in the structure of the exposed form mainly connected to the gabion to be integrated with each other. Due to its shape, there was a problem in that a demanding work and maintenance cost that requires maintenance by mobilizing separate equipment is increased.

Accordingly, in order to solve the above problems, the present inventors can mass-produce a lattice-type hollow block for ecological restoration as a unit united at the factory to enable the shape maintenance, and facilitate transportation and installation work. In the field, it is possible to take the form of construction work that is buried in the ground through simple assembly work, improve the productivity according to the installation, reduce the installation cost (labor cost, equipment cost, etc.), and embankment constructed with lattice hollow blocks The present invention is to provide a habitat for aquatic organisms such as fish in the waterfront area of the slope, and to provide a habitat for animals by forming plants of herbaceous and woody plants in the slope part, thereby restoring the natural ecosystem to provide a hydrophilic space in harmony with nature. It was created.

Hereinafter, the term "reservoir preservation block" means a lattice-type hollow block buried at the bottom of the waterside zone at the slope slope, and the "slope block" is a grid embedded at an inclined slope portion from the top of the bank to the slope slope. It means a hollow hollow block, and the term "wedge shaped support block" means an inclined space formed between the preservation block and the slope block, and an inclined space formed between the slope block and the barrier, that is, between two lattice hollow blocks. It means a block embedded in a space formed in the support buried.

In addition, the “basic hollow block” is a lattice hollow block in which a neighboring lattice hollow block and the outer surface of the edge are coupled by linear contact, and a “protrusion hollow block” is a horizontal frame composed of a pair of up and down pairs of neighboring lattice hollow blocks. It refers to a lattice-shaped hollow block to the concave-convex coupling on the four outer edges (sides), the shape and structure other than that is the same as the basic hollow block.

The present invention is a block embedded in the ground of riversides, lakes, banks, slopes, the quality of the hollow products united to maintain the shape of the product is manufactured by ensuring quality, it is possible to mass-produce in the factory, and also filled in the field The present invention provides a lattice-type hollow block for ecological restoration of a levee and a construction method of a levee using them.

In addition, the present invention is in the form of a unitized product, by simply transporting and assembling to the location in the field, the handling and assembly are easy, and the construction and economics are good, and the construction period required to build the dike can be greatly shortened. The present invention provides a lattice-type hollow block for ecological restoration of a dike and a construction method of a dike using the dike.

In addition, the lattice-type hollow block for ecological restoration of the present invention is connected to each other integrally connected and buried in the ground to have structural stability, as well as simple assembly installation is possible without the need for additional equipment, the existing gabion gabion The present invention provides a lattice hollow block for ecological restoration of banks and a construction method of banks using them.

In addition, the embankment construction method using the grid-type hollow blocks for embankment ecological restoration of the present invention, by filling the river aggregate in the vicinity of the vicinity as a filling material, greatly reducing the construction cost, such as material costs, and only in the case of damage The present invention provides a lattice-type hollow block for ecological restoration of a levee and an embankment construction method using them, which can be easily replaced and repaired, thereby reducing maintenance costs.

In addition, aquatic habitats such as fish are provided in the waterfront area of the embankment constructed with the lattice-shaped hollow blocks of the present invention, and plants of herbaceous and woody species form forests at the slopes to provide animal habitats, respectively, to achieve hydrophilic harmony with nature. The present invention provides an environmentally friendly lattice hollow block for ecological restoration and a dike construction method using them.

The present invention relates to a horizontal frame which is spaced apart from each other by a predetermined distance while forming an opening having a central portion, and a vertical hollow is integrally connected between the horizontal frames to form a hollow portion having a predetermined volume inwardly. In the lattice-shaped hollow block consisting of a structure of the skeleton supporting skeleton having a three-dimensional grid,
Auxiliary grooves are formed to form anchoring holes penetrating vertically at predetermined positions of each side while closing the opening in a predetermined flat form, and each auxiliary side has a fitting space having a short fitting space from the outer edge of the edge and extends from the auxiliary groove. Horizontal projections having a predetermined length projecting outwardly, having a groove portion extending from the projection portion having a fitting space having the size of the projection portion, and an auxiliary projection portion extending from the groove portion to protrude to the length of the auxiliary groove portion outwardly; And a plurality of vertical members which are anchored at the center of the cross section so as to coincide with the anchor coupling holes formed at predetermined positions of the horizontal frames, and are vertically connected and vertically supported between the upper and lower horizontal frames. Grooves and protrusions formed on each side of the horizontal frame, and adjacent to Provides a grid-shaped hollow blocks for the banks of ecological restoration, it characterized in that the projection and the groove portions to be formed for each of the horizontal frame, which is installed gakbyeon coupled to each other irregular form.

In addition, the present invention provides a lattice-type hollow block for ecological restoration of the embankment, characterized in that the connection fixing pin coupling holes are vertically penetrated at appropriate positions of the horizontal frames constituting the upper and lower pairs, respectively.

In addition, the present invention provides a grid-type hollow block for ecological restoration of the embankment, characterized in that the planar form of the horizontal frame constituting the upper and lower pairs is composed of any one of a square, a rhombus or a polygonal form.

In another aspect, the present invention provides a lattice hollow block for ecological restoration of the embankment, characterized in that it further comprises a configuration in which the nonwoven fabric is integrally attached to the upper surface of the horizontal frames located on the lower side.

delete

In addition, the present invention provides a grid-like hollow block for ecological restoration of the embankment, characterized in that the frame-like skeleton supporting frame consisting of the horizontal frame and the vertical member is made of a plastic injection molding.

On the other hand, the present invention is the step of cutting or filling the embankment slope from the waterside area to the upper end of the slope after the surface evenly formed to form a base bottom; Laying a barrier over the bottom of the foundation and then laying a mesh network (geonet) over the barrier; Grooved lattice-type hollow blocks for ecological restoration of the embankment are arranged in order from the waterside area at the bottom of the embankment to the top of the slope to the upper side of the laid mesh network (geonet); The grid-like hollow that is assembled and assembled by the uneven coupling of the protrusions, and is anchored to the base plate by inserting anchors in a plurality of anchor coupling holes formed in the vertical members and the horizontal frames forming the pair of the grid-shaped hollow blocks, respectively. Connection assembly installation and ground fixing step of blocks; Filling the fillers of gravel and rubble into the hollows of the grid-type hollow blocks fixed in the base; Forming a soil layer by laying soil having a predetermined thickness on the soil filled with plant seeds and the subleaf soil to the filling side; Laying a soil coating for preventing soil loss to the upper side of the soil layer, and then laying a mesh network (geonet); A method of constructing a levee using lattice-type hollow blocks for embankment ecological restoration, characterized in that comprising the step of fixing the laid soil cover and the mesh net (geonet) into the soil layer by a fixing pin. do.

In addition, the present invention in the connection assembly installation and ground fixing step of the lattice-type hollow blocks, the upper and lower horizontal frames and the vertical members to form the pair of rafts preservation blocks installed in the waterfront area of the bottom of the embankment in a plurality of layers It provides a construction method of the embankment using the lattice-type hollow blocks for ecological restoration of the embankment, characterized in that the buried anchor in the ground of the river bottom while connecting the anchors integrally connected to a plurality of anchoring holes formed in each.

In addition, the present invention is connected to each other in the space formed between the preservation blocks installed in the waterfront area of the bottom of the bank and the slope blocks installed on the slope of the bank in the connection assembly installation and ground fixing step of the grid-shaped hollow blocks To support the wedge-shaped support blocks are provided along the longitudinal direction of the river at a predetermined interval or continuously provided for the construction of the embankment using the grid-type hollow blocks for ecological restoration of the embankment.

In addition, the present invention in the connection assembly installation and ground fixing step of the lattice-shaped hollow blocks, the banks of the preservation block is installed in the waterfront area of the bottom of the embankment so that the leading end is arranged in the downstream direction to induce water flow from the upstream gently It provides a construction method of the embankment using the grid-shaped hollow blocks for embankment ecological restoration that is installed.

In addition, the present invention in the connection assembly installation and ground fixing step of the lattice-type hollow blocks, while the reservoir preservation blocks installed in the waterfront area of the bottom of the embankment protrudes one or more layers from the reservoir preservation blocks embedded in the ground of the river bed It provides a construction method of the embankment using the grid-type hollow blocks for ecological restoration of the embankment, characterized in that the fish habitat space is formed by alternately installed in a plurality of units or at regular intervals along the length of the river.

Therefore, the lattice hollow block for ecological restoration of the present invention can be mass-produced in a standardized quality as a unit united in the factory to maintain the shape, and a separate shape assembly work is required to accommodate the filling material in the field. There is no advantage.

In addition, the lattice-type hollow block for ecological restoration of the present invention is a lightweight product in the form of a unit, which can be transported to a corresponding installation location by an operator alone, and can be used without distinction between front and rear, and simply arranged and connected in the field. By assembling, it is easy to handle and assemble, so that the workability and economics are good, and the construction time required for building the levee can be greatly shortened.

In addition, the lattice-type hollow blocks for ecological restoration of the present invention are connected to each other integrally connected and buried in the ground to have structural stability, and can be easily assembled and installed without mobilizing additional equipment, and the existing gabion gabion There is an advantage to fundamentally solve the concern of safety accidents such as injuries of workers due to the shape maintenance work after putting the stone in the mesh during work.

Embankment construction method using the grid-type hollow blocks for ecological restoration of the embankment of the present invention by using the river aggregate in the vicinity as a filling material, there is an advantage in economic efficiency by greatly reducing the construction cost, such as material costs, and also in case of damage By replacing only the lattice hollow block, there is an advantage that the replacement and maintenance can be easily performed, thereby reducing the maintenance cost.

Most importantly, the waterfront area of the embankment constructed with the lattice-shaped hollow blocks of the present invention has habitats for aquatic organisms such as fishes, and on the slopes, green plants have forests of herbaceous and woody plants to provide animal habitats. By being possible, there is an environmentally friendly advantage to restore the natural ecosystem to provide a hydrophilic space in harmony with nature.

Hereinafter, the technical details of the present invention by the accompanying drawings in detail.

3 to 6, the lattice-shaped hollow block for ecological restoration of the present invention is a vertical frame spaced apart from each other by a predetermined distance while forming an opening having a central portion, and is vertical between the horizontal frames. In the lattice-shaped hollow block consisting of a structure of the frame-like skeleton support frame of the grid-like three-dimensional shape having a hollow hollow (S) of a predetermined volume inwardly connected to the member integrally,
Auxiliary groove portion 13 having anchoring holes 11a vertically penetrating at predetermined positions of each side while closing the opening in a predetermined plane shape, and having a fitting space having a short length from the outer edge of the edge continuously in each side; And a groove portion 15 extending from the auxiliary groove portion 13 and protruding outwardly, the groove portion 15 extending from the protrusion portion 14 and having a fitting space having the size of the protrusion portion 14, and Horizontal frames 10 having an auxiliary protrusion 16 extending from the groove 15 and protruding outwardly to the length of the auxiliary groove 13;
Anchor coupling holes 21a are formed at the center of the cross section to coincide with the anchor coupling holes 11a formed at predetermined positions of the horizontal frames 10 to be vertically connected and supported integrally between the upper and lower horizontal frames 10. Consists of a plurality of vertical members 20,
The grooves and the protrusions formed on each side of the horizontal frames, and the protrusions and the grooves formed on each side of the horizontal frames installed adjacent thereto are coupled to each other in an uneven form.

The grid-type hollow block for ecological restoration of the embankment of the present invention is characterized in that the planar shape of the horizontal frames 10 forming the upper and lower pairs is formed of any one of a quadrangle, a rhombus, and a polygonal shape.

Hereinafter, a description will be given of the lattice-shaped hollow blocks of the horizontal frame 10 made of a rectangular shape, which is manufactured in the factory as a skeleton support frame of the three-dimensional grid shape in the form of a square, rhombus or polygonal Let's find out.

The lattice-type hollow block for ecological restoration of the present invention is roughly divided into two types: a basic hollow block having four outer ends of the horizontal frames 10 forming a vertical pair and a straight hollow block having protrusions and protrusions. First, the main components of the basic hollow block will be described in detail.

As shown in Figures 4a to 5, the basic hollow block has a rectangular horizontal frame (10) consisting of four sides in the horizontal direction of the structure and shape of the upper and lower pairs, and the horizontal frame 10 of the pair Consists of vertical members 20 that are integrally supported in the vertical direction between the two, as a skeleton support skeleton of the rectangular parallelepiped, to form an opening (O) is open six sides in the vertical direction, left, right, front and rear direction, the inside of which will be described later It is formed in a structure having a hollow portion (S) for receiving the filling material.

The horizontal frame 10 in the horizontal direction of the frame support skeleton of the grid-like three-dimensional shape is a rectangular frame consisting of four sides, four anchor coupling holes (11a) are formed at the center of the corner portion, both anchor coupling holes Connection fixing pin coupling holes 12 are formed for each side at regular intervals in the longitudinal direction of the horizontal frame 10 between the (11a).

On the other hand, the horizontal frame 10 of the grid support frame of the grid-like three-dimensional shape may be formed of a quadrilateral or rhombus frame, a polygonal frame made of multilateral sides as described above, The three-dimensional shape of the hollow portion S is formed of a cube, a cube, and a polygon of a polygon.

Anchor coupling holes 11a of the horizontal frame 10 (holes formed only on the horizontal frame member) are anchor coupling holes 21a of the vertical members 20 (holes formed only on the vertical member). It is formed in the same shape and size as the anchor (A) is inserted into the holes in the upper side to be fixed into the base (F), and the connection fixing pin coupling holes 12 are adjacent horizontal frame (10) The grid U-shaped connection fixing pins (not shown) between the grid-shaped hollow blocks, while the function of connecting the filling material 500 filled in the interior of the grid-shaped hollow block to be described later so as not to leave It also serves as an auxiliary function to support the filling material filled in the hollow block into the frame.

The vertical vertical members 20 of the frame support frame of the grid-like three-dimensional shape are vertically connected integrally between the horizontal frames 20 at the four corners of the horizontal frames 20 that form the upper and lower pairs. As the member to be anchored, anchoring holes 21a penetrated on the center axis line are formed, respectively.

In addition, the reinforcing portions 22 are formed on the inner surface of each corner portion contacting the horizontal frames 20. It is noted that this is formed so as not to break by increasing the support strength of the contact edge portion.

On the other hand, it is preferable that the vertical members 20 in the vertical direction connected between the horizontal frames 10 in the horizontal direction of the skeleton support frame of the lattice-shaped three-dimensional shape are installed at each of the bent portions that are angled by the flat shape. .

In addition, the non-woven fabric 30 is further provided on the upper surface of the horizontal frame 10 positioned below the skeleton support frame of the lattice-shaped three-dimensional frame, it is revealed that the nonwoven fabric is manufactured and used in a factory as a lattice-type hollow block.

The nonwoven fabric 30 is a member that is integrally bonded to the upper surface of the lower horizontal frame of the lattice hollow block, to prevent the loss of the soil of the soil layer and the plant seeds sprayed on the soil from rainwater from the top of the lattice hollow block of the lattice hollow block It serves to tightly fill between the pores of the fillers to be filled in the hollow formed therein.

This is so that plant seeds sown in the soil layer to be described later germinate without far from the soil layer so that plant seeds can be firmly deeply rooted.

As another embodiment of the basic hollow block, as shown in Figure 6a to Figure 7, in the basic hollow block structure having a shape of the concave-convex portion that is easy to assemble up and down side connection, only the horizontal frame 10 is deformed structure As a projection hollow block formed by the neighboring, the neighboring lattice-like hollow blocks in the assembled assembly between the four sides of the horizontal frame 10 constituting the upper and lower pairs neighboring by the concave-convex coupling consisting of the projection and the groove from the outer end of each side Is an embodiment that can be connected between the projection hollow block.

In more detail, as shown in Figure 8, the four sides of the horizontal frame (10) forming a square structure having alternately successive projections and grooves from the outer end on each of the four sides of the upper and lower pairs, and thus the neighboring lattice It is provided with a structure in which any side of the four sides are in contact with each other while being in contact with the hollow blocks.

That is, the auxiliary groove 13 having a fitting space having a short length from the outer edge of one side to the inner side in the same direction for each side of each horizontal frame 10 forming the upper and lower horizontal plane of the skeleton support frame of the grid-like three-dimensional structure ) And a protrusion 14 having a predetermined length extending from the auxiliary groove 13 to protrude outward, and extending from the protrusion 14 to form a fitting space having the size of the protrusion 14. The groove 15 is formed to be concave and convex, and extends from the groove 15 to protrude outwardly, and has a structure having alternately short auxiliary protrusions 16 that are concave and convex to the size of the auxiliary groove 13. Is formed.

According to another embodiment of the present invention as described above, since the specific configuration other than the configuration provided continuously with the groove portion and the projection from the outer end is the same as in the embodiment of the basic hollow block of the present invention described above, further detailed description It will be omitted.

On the other hand, the horizontal frame 10 in the horizontal direction of the frame support skeleton of the grid-like three-dimensional structure, even when formed in a quadrilateral frame, a rhombus frame, a polygonal frame consisting of multi-sided grooves and protrusions on the outer end, respectively It turns out that it can have a form that is concavely convex by forming alternately.

The basic type or protrusion hollow block as described above is a horizontal frame 10 and a vertical member 20 constituting the upper and lower pairs constituting the skeleton support frame of the three-dimensional shape of the skeleton is produced as a lattice structure by factory production as a unit Lose.

The lattice-shaped skeleton supporting frame is preferably made by injection molding integrally with plastic, but made of wood or steel structural members (eg, rods, angles, channels or square sections, and pipes or pipes). It should be noted that the structural members of the lightweight form steel) may be manufactured by assembling each structural member.

In other words, the embodiments that are applied to the embankment modified to the grid-like structure of the shape, such as the skeleton-supported skeleton of the above-described grid-like three-dimensional shape is within the scope of the present invention.

The size of the grid-shaped hollow block consisting of the rectangular frame, the horizontal frame 10 is 1m each, horizontally and vertically, the vertical member 20 is about 30cm in height, the weight is about 30kg light weight product Since the unit is manufactured in a factory, it can be transported and handled by the worker alone, thereby reducing the cost of installation. However, the present invention is of course not numerically limited in size and weight of the lattice hollow block.

The lattice hollow block of the present invention is a factory product, due to the shape of a unitized product having a lattice structure, it is possible to maintain the shape and mass production of the product, and also to easily handle and transport on-site, No transport or handling equipment is required, and it can be used without any front and back separation (except for hollow block integrated with non-woven fabric). Has the form of.

<Construction order>

The construction method of the embankment using the lattice-type hollow blocks for embankment ecological restoration of the present invention, as shown in Figure 3, 9 and 10, the bank slope (L) of the slope from the waterfront area (W) to the slope Cutting or filling up to an upper end to form a foundation bottom part 100 by evenly arranging the surface; Laying the order layer 200 on the upper side of the foundation bottom part 100, and then laying the mesh network (geonet) 300 on the upper side of the order layer; The lattice hollow blocks 400 for the ecological restoration of the embankment are arranged in order from the waterside area at the bottom of the embankment to the upper slope of the embankment to the upper side of the laid mesh network (geonet) 300. A plurality of anchors formed in the vertical and horizontal members 10 and the horizontal frame 10 and the vertical member 20, which are connected and assembled integrally by the concave-convex coupling of the grooves and the projections alternately formed in the grid-shaped hollow block 400; Connection assembly installation and ground fixing step of lattice-shaped hollow blocks for fixing anchors (A) in the coupling holes (11a) (21a) to be fixed to the base (F); Filling gravel and rubble filler 500 into the hollow part S of the grid-shaped hollow blocks 400 fixed in the base plate F; Forming an earth and sand layer (600) by laying the earth and sand mixed with plant seeds and subleaf soil with a predetermined thickness to an upper side of the filling material (500); Laying a soil coating for preventing soil loss 700 on the upper side of the soil layer 600, and then laying a mesh net (geonet) 800; And fixing the laid soil coating for preventing soil loss 700 and the mesh net (geonet) 800 into the soil layer 600 by the fixing pin 900.

On the other hand, in the connection assembly installation and ground fixing step of the lattice-shaped hollow block, the upper and lower horizontal frame (10) is installed in a plurality of layers to be installed in the waterfront area (W) at the bottom of the embankment horizontal pair (10) ) And a plurality of anchor coupling holes (11a) (21a) formed in the vertical member (20), respectively, by anchoring the anchor (A) integrally connected to be embedded in the base plate (F) of the river bottom.

This is because the lakeside preservation block (400a) disposed in the lower waterside zone (W) is installed in a plurality of layers, because the weight due to gravity is formed as an integral structure, the ground is scoured due to the flow rate of water flowing through the river is broken or heap To avoid being washed away.

In addition, the preservation block 400a disposed in the lower waterside zone (W) is filled with earth and sand between the gaps between the filling material 500 filled therein, the uppermost reservoir block 400a installed in parallel with the river bed The upper surface of) is used as aquatic organisms and fish habitat space (S) by creating aquatic plants to grow by the sediment of the soil coming from the river.

In the connection assembly installation and ground fixing step of the grid-shaped hollow blocks, formed between the banks of the preservation block (400a) is installed in the waterfront area (W) at the bottom of the bank and the slope blocks (400b) are installed on the slope of the bank The wedge-shaped support blocks 400c are installed at regular intervals or continuously along the longitudinal direction of the stream so as to be connected to each other in the space, thereby being formed between the bent spaces formed between the preservation blocks 400a and the slope blocks 400b. It is located on the shoreline to be integrated between the preservation block (400a) and the slope block (400b) to support the function of complementing the weakness of the structural support strength.

The wedge-shaped support block 400c may also be manufactured as a three-dimensional lattice structure formed of the horizontal frames 10 and the vertical members 20, such as the preservation block 400a and the slope block 400b. Reveal it.

In the connection assembly installation and ground fixing step of the lattice-shaped hollow blocks, shoreguard block (400a) is installed in the waterfront zone (W) at the bottom of the embankment, the front end is arranged in the downstream direction to gently induce the water flow from the upstream To be installed.

This is to protect the structure by inducing the water flow in the river flows smoothly by installing the lakeside preservation block 400a disposed in the lower waterside zone (W) to the downstream, and to reduce the resistance of the flow rate.

In the connection assembly installation and ground fixing step of the lattice-type hollow blocks, the banks of the banks preservation block (400a) installed in the waterfront area (W) of the bottom of the embankment buried in the original ground (F) of the river bed (400a) It is revealed that the fish habitat space (C) formed by alternately installed in a plurality of units or a predetermined interval along the longitudinal direction of the river while protruding one or more layers from the field.

This is to provide the fish habitat space (C) to protrude more than one layer from the shoreline preservation block (400a) buried in the base ground (F) of the river bed, while the plurality of units in the longitudinal direction of the stream, that is, the plane In the case of continuous installation of the furnace, the flow rate of water flowing along the longitudinal direction of the river is relatively fast, so that the force against the structure is strong, so as to protect the structure.

On the other hand, when installed alternately in the longitudinal direction of the river, that is, in a plane at regular intervals, since the water flow rate is low and the force against the structure is also weak, a plurality of fish habitat spaces (C) are formed intermittently and variously in the river. It can be used as a habitat for aquatic creatures and fish.

It will be described in detail step by step for the construction method of the embankment using the lattice hollow blocks for ecological restoration of the embankment as described above.

1. forming a lower waterfront (W) and slope (L) clearance of the embankment;

After cutting or filling the ground surface (F) of the waterside zone (W) and the slope (L) of the embankment, it is a step of surface trimming evenly to form a base bottom (100). Since this is a conventional method, a detailed description thereof will be omitted.

2. laying curtain and geonet (mesh);

After the foundation bottom portion 100 is formed as described above, a water barrier film 200 having a function of ordering is installed above the foundation bottom portion so that water does not penetrate into the base surface of the slope, and the mesh net 300 is laid thereon. do.

3. Hollow block assembly installation and hollow block fixing step on the base by the anchor;

First, the banks of the waterfront area (W) to be installed in a plurality of layers by installing the banks of the preservation block (400a) buried in the ground and anchoring holes (11a) formed in the horizontal frame 10 and the vertical member 20 of the upper banks of the preservation block ) A plurality of anchors (A) in the (21a) is fixed to the shore preservation block (400a) installed in a plurality of layers integrally to the base (F). At this time, the anchor (A) is installed using the anti-corrosion galvanized.

Subsequently, after installing the wedge-shaped support blocks 400c which are assembled and assembled to the preservation block 400a at the boundary between the waterside zone W and the slope L, the lowest end supported by the wedge-shaped support blocks 400c. Assembling and installing the inverted U-shaped fixing pins (not shown) between the slope blocks 400b of the to complete the installation of the slope blocks 400b to the upper side of the bank continuously in the upward direction. Preferably, the slope block 400b installed at the upper side of the bank is preferably installed up to the maximum level of water level.

In this case, as described above, the preservation block (400a) is fixed to be embedded in the ground of the river floor, as shown by the dotted line of Figure 10, depending on the topographic conditions of the river, can be installed to protrude more than one floor from the river floor. Let's find out.

As shown in FIG. 9, the location where the protrusion is formed is installed at a suitable place for aquatic organisms and fish, that is, the river is wide and the flow rate is gentle to form the fish habitat space (C). On the contrary, it should be noted that the structures forming the protrusions may not be formed in the form of the protrusions formed continuously in the longitudinal direction of the river or embedded in the base of the river bed at the portion having a high flow rate or curve.

In addition, the portion protruding from the surface of the base plate (F) may be installed continuously to the upper side, which is to ensure more underwater space, and may also be installed alternately in a zigzag form in the longitudinal direction of the steel as described above. same.

In the above-described lattice-shaped reservoir preservation block (400a) is a place where the flow velocity is a slow terrain conditions using a product manufactured in the form of a rectangular planar structure in a linear direction along the width direction, but the front end portion of the structure When installed inclined as it is not specifically shown, but puts out that can be installed in the form having a triangular planar structure.

On the other hand, the connection assembly between the lattice-shaped hollow block, the anchor (A) is fitted in the anchor coupling holes (11a) (21a) formed to penetrate the horizontal frame 10 and the vertical member 20 in the vertical direction Inverted U-shaped fixing pins having fixing shapes fixed in the base plate F and fixed pin coupling holes 12 formed in the horizontal frames 10 between the adjacent lattice-shaped hollow blocks in left and right directions. Or it has a coupling form by a clip (not shown).

At this time, the length of the inverted U-shaped fixing pin preferably has a length extending to the horizontal frame 10 located on the lower side, which is the filling material 500 is filled in the hollow portion (S) of the inner space of the grid-shaped hollow block It supports to prevent it from escaping to the outside.

4. Filler filling in lattice-type hollow block buried in the ground;

The filler 500 is filled in the inner hollow portion (S) of the lattice-shaped hollow block, is filled by using rubble and gravel laid around the river where the structure is installed, the filler is 90 ~ 300㎜ particle size As a degree, the hollow portion S formed inside the lattice hollow block is filled in an irregular shape.

5. A soil layer laying step of mixing plant seeds and subleaf soil with a predetermined thickness on the upper side of the lattice block filled with filler;

After the filling material 500 is filled, the foliar soil or compost is mixed with earth and sand to install a soil thickness layer 600 having a predetermined thickness by installing it on the upper side of the lattice block with a certain thickness with plant seeds.

At this time, the thickness of the soil layer 600 should be laid at a minimum thickness of about 300 mm, in order to facilitate the growth and rooting of the root of the plant, on the other hand, the soil or compost is naturally fermented by the microorganisms Germinated plant seeds function to provide the nutrients needed to grow.

As described above, the present invention can artificially create an optimal growth environment that can promote germination and growth of plant seeds, and thus has the advantage of providing faster and more reliable greening.

6. Soil coating to prevent loss of soil layers and laying of geonets (mesh);

The soil coating for preventing soil loss 700 serves as a cover for covering the soil layer 600 with a nonwoven fabric (blanket) and the like.

This reduces the falling pressure of rainwater falling on the soil layer 600 installed above the lattice block to prevent direct impact on the soil, thereby preventing the soil layer 600 from being scoured or eroded during rainwater. In addition to preventing the loss, by preventing the loss of plant seeds contained in the soil of the soil layer 600 and the evaporation of moisture in the soil layer by maintaining a wet state in the soil layer 600 to promote the growth of plant seeds.

On the other hand, the non-woven fabric (blanket) is a material that is installed as the soil coating for preventing the loss of soil (blanket) has the advantage of covering the slope (L) with a uniform thickness without excessively phenomena occurring on either side. There is a, as the greening and stabilization after construction, after a certain period of time to leave the blanket is naturally decomposed.

The mesh network (geonet) 800 is made of a flexible grid of polyester material, so that it can be handled as easily as possible by rolling both during construction and transportation, even after the slope (L) is green and stabilized after construction It remains and functions to prevent soil loss continuously.

7. Settling of the soil layer by the soil coating and the fixing pin of the mesh network (geonet);

After the installation of the soil coating 700 and the mesh network (geonet) 800, the soil coating 700 and the mesh network (geonet) 800 with fixed pins 900 at a predetermined interval from the upper side By fixing the sediment in the soil layer 600, the soil coating 700 and the mesh net (geonet) 800 by the external force to provide a function that does not separate from the soil layer to more reliably of the soil layer 600 By preventing the loss of soil, it is possible to promote the germination and growth of the seeded plant seeds.

The fixing pin 900 is preferably in the form of an inverted U, and allows the fixing pin 900 to be more accurately and firmly fixed in position so as to be bound to any one of the string or the blade of the mesh net 800. This is preferred.

The construction method of the embankment using the lattice hollow blocks for ecological restoration of the embankment, which is made as described above, is constructed by manufacturing the lattice hollow blocks united in a factory so as to maintain a constant shape and bringing them into the site and installing them. Good, can shorten the construction period, reduce the construction cost, the safety of the operator and the easy maintenance of the structure, and the embankment by integrally embedded between the grid hollow blocks in the ground The structural stability of the structure can be achieved.

Therefore, the present invention constructed as described above, the habitats of insects and animals by melting the herbaceous and woody on the slopes of the embankment, the fish habitat space (C) is formed in the waterfront area to provide a habitat for aquatic life, respectively It is an eco-friendly and useful invention that restores and has a hydrophilic space in harmony with nature.

1 is a side cross-sectional view using a relief block according to the prior art,

Figure 2 is a side cross-sectional view using a relief block according to the prior art,

Figure 3 is an overall side cross-sectional view of the embankment structure according to the present invention,

Figure 4a is a perspective view of the basic hollow block for ecological restoration according to the present invention,

Figure 4b is a plan view of the basic hollow block of Figure 4a,

Figure 4c is a side view of the basic hollow block viewed from one side of Figure 4b,

5 is a perspective view of a modified embodiment of the basic hollow block for ecological restoration according to the present invention (non-woven fabric attached),

Figure 6a is a perspective view of the ecological restoration projection hollow block according to the present invention,

Figure 6b is a plan view of the projection hollow block of Figure 6a,

Figure 6c is a side view of the projection hollow block viewed from one side of Figure 6b,

Figure 7 is a perspective view of a modified embodiment of the ecological restoration protrusion hollow block according to the invention (non-woven fabric attached),

8 is a plan view showing a connection between the projection hollow block of the present invention,

Figure 9 is a plan conceptual view of the bank structure applied to the riverbank in accordance with the present invention (concept of the tip end of the preservation block is disposed in the downstream slope to form a fish habitat space),

10 is a cross-sectional view of the embankment structure constructed using the grid-type blocks for ecological restoration of the present invention.

<Description of Symbols for Main Parts of Drawings>

 10: horizontal frame 11a, 21a: anchor coupling holes

 12: Hole for coupling retaining pin 13: Auxiliary groove (small groove)

 14: projection (large protrusion) 15: groove (large groove)

 16: auxiliary protrusion (small protrusion) 20: vertical member

 22: reinforcement part 30: nonwoven fabric

100: base bottom portion 200: curtain

300: mesh network (geonet) 400: lattice hollow block

400a: Slope Preservation Block 400b: Slope Block

400c: wedge-shaped support block 500: filler (rubble and gravel)

600: soil layer 700: soil coating to prevent soil loss

800: mesh network (geonet) 900: fixed pin

O: opening S: hollow part

F: Ground (river, slope bottom) W: Waterside area

L: bank slope (lower, upper slope) A: anchor

C: Fish habitat

Claims (11)

A horizontal frame formed by opening a central portion and spaced apart from each other by a predetermined distance from each other, and a vertical member is integrally connected between the horizontal frames, and has a hollow portion S having a predetermined volume inwardly. In the lattice-shaped hollow block consisting of a structure of a skeleton-supported skeleton of a three-dimensional grid, Auxiliary groove portion 13 having anchoring holes 11a vertically penetrating at predetermined positions of each side while closing the opening in a predetermined plane shape, and having a fitting space having a short length from the outer edge of the edge continuously in each side; And a groove portion 15 extending from the auxiliary groove portion 13 and protruding outwardly, the groove portion 15 extending from the protrusion portion 14 and having a fitting space having the size of the protrusion portion 14, and Horizontal frames 10 having an auxiliary protrusion 16 extending from the groove 15 and protruding outwardly to the length of the auxiliary groove 13; Anchor coupling holes 21a are formed at the center of the cross section to coincide with the anchor coupling holes 11a formed at predetermined positions of the horizontal frames 10 to be vertically connected and supported integrally between the upper and lower horizontal frames 10. Consists of a plurality of vertical members 20, The grating hollow block for embankment ecological restoration, characterized in that the grooves and protrusions formed on each side of the horizontal frame, and the protrusions and grooves formed on each side of the horizontal frames installed adjacent thereto are coupled to each other in an uneven form. The method of claim 1, wherein the grid fixed hollow block for embankment ecological recovery, characterized in that the connection fixing pin coupling holes 12 which are vertically penetrated at each suitable position of the horizontal frame 10 constituting the upper and lower pairs are formed. . The method of claim 1, wherein the flat form of the horizontal frame constituting the upper and lower pairs 10 grating hollow block for ecological restoration of the embankment, characterized in that consisting of any one of the form of a square, rhombus or polygon. According to any one of claims 1 to 3, Ecological restoration grid grating characterized in that it further comprises a configuration in which the non-woven fabric 30 is integrally attached to the upper surface of the horizontal frame 10 located on the lower side. Type hollow block. delete According to claim 1, wherein the grid support frame of the three-dimensional grid structure consisting of the horizontal frame 10 and the vertical member 20 is made of a plastic material injection molding lattice hollow of the ecological restoration block. Cutting the embankment slope (L) from the waterside zone (W) to the upper end of the slope, and then surface trimming to form a foundation bottom (100); Laying the order layer 200 on the upper side of the foundation bottom part 100, and then laying the mesh network (geonet) 300 on the upper side of the order layer; The grid-type hollow blocks for ecological restoration of the embankment according to claim 1 are arranged in the order from the waterside area at the bottom of the embankment to the top of the slope to the upper side of the laid mesh network (geonet) 300. A plurality of anchors formed in the horizontal frame 10 and the vertical member 20, which are integrally connected and assembled by uneven coupling of grooves and protrusions alternately formed at the ends and forming a vertical pair of grid-shaped hollow blocks 400, respectively. A connection assembly installation and ground fixing step of the lattice-shaped hollow blocks 400 for fixing the anchors A into the coupling holes 11a and 21a to be fixed to the base F; Filling gravel and rubble filler 500 into the hollow part S of the grid-shaped hollow blocks 400 fixed in the base plate F; Forming an earth and sand layer (600) by laying the earth and sand mixed with plant seeds and subleaf soil with a predetermined thickness to an upper side of the filling material (500); Laying a soil coating for preventing soil loss 700 on the upper side of the soil layer 600, and then laying a mesh net (geonet) 800; The soil coating agent for preventing soil loss 700 and the mesh network (geonet) 800 is fixed to the soil layer 600 by the fixing pin 900; Ecological restoration of the embankment, characterized in that consisting of Embankment construction method using lattice hollow blocks. The dike according to claim 7, wherein in the connection assembly installation and ground fixing step of the lattice-type hollow blocks, the bank security preservation block (400a) installed in the waterfront area (W) at the bottom of the embankment is installed in a plurality of layers Embankment construction method using lattice hollow blocks for ecological restoration. According to claim 7, In the connection assembly and ground fixing step of the lattice-shaped hollow block, slope block 400b installed on the slopes of the banks and the preservation block (400a) installed in the waterfront area (W) of the bottom of the embankment ) The construction method of the embankment using lattice-type hollow blocks for ecological restoration of the embankment, characterized in that the wedge-shaped support blocks 400c are installed at regular intervals or continuously along the length direction of the river so as to be connected to each other in a space formed between the two. . According to claim 7, In the connection assembly installation and ground fixing step of the lattice-shaped hollow blocks, the shore guard block (400a) is installed in the waterfront zone (W) at the bottom of the embankment, the front end is arranged in the downstream direction from the upstream Embankment construction method using lattice-type hollow blocks for ecological restoration of the embankment, characterized in that it is installed to gently induce the water flow. According to claim 7, In the connection assembly installation and ground fixing step of the lattice-shaped hollow blocks, the lakeside preservation block (400a) installed in the waterfront area (W) at the bottom of the embankment is buried in the base (F) of the river bed A lattice type for embankment ecological restoration, characterized in that the fish habitat space (C) formed by alternately installed in a plurality of units or at regular intervals along the longitudinal direction of the river while protruding one or more layers from the shoreline preservation blocks (400a) Embankment construction method using hollow blocks.

Images