KR100629155B1 - Squre gabion - Google Patents

Abstract

The present invention relates to a rectangular gabion.

According to the present invention, four side wire meshes are combined in a box shape at the edges of the bottom wire meshes, and the upside wire meshes are coupled to the upper portions of the side wire meshes, and the bottom wire meshes, the side wire meshes, and the upside wire meshes are horizontally and vertically. In the rectangular gabion structure formed in a lattice form at a predetermined pitch, the side wire mesh is composed of a front wire mesh and a rear wire mesh at the front and rear, respectively, and a left wire mesh and a light wire mesh between the front wire mesh and the rear wire mesh. It is characterized in that the front wire mesh and the rear wire mesh is configured to be pulled by the tension control.

Therefore, the present invention is to prevent the bulge phenomenon that the front surface of the gabion combined in the form of a box popping out by the pressure of the stone, and some of the gabions constructed by lengthening the reinforcing rod to prevent the shape of the It is designed to prevent protruding or sinking more than other gabions, and to prevent cuts while preventing flooding by being installed on the shore of a river or on the surface of a river.

Bottom wire mesh, side wire mesh, gabion, tension control unit, binding wire

Description

Square Gabion {Squre Gabion}

1 is a perspective view of a gabion in accordance with the present invention.

Figure 2 is an exploded perspective view of the gabion according to the present invention.

Figure 3 is a perspective view showing a state in which the left gabion mesh removed in accordance with the present invention.

Figure 4 is a longitudinal cross-sectional view of the gabion according to the present invention.

Figure 5 is an exemplary view showing a state filled stone in the gabion in accordance with the present invention.

Figure 6 is an illustration showing a state of use of the gabion in accordance with the present invention.

7 is an exemplary view showing a state in which the gabion according to the present invention is constructed on a law surface having a large inclination angle.

8 is an exemplary view showing a state in which the gabion vertically stacked according to the present invention.

Figure 9 is an illustration showing the opponent constructed on the gabion in accordance with the present invention a small slope angle.

<Brief description of symbols for the main parts of the drawings>

100: bottom wire mesh 200: side wire mesh

210: front wire mesh 220: rear wire mesh

230: left wire mesh 240: light wire mesh

250: tension adjusting unit 251, 251 ': first seat, second seat
252,252 ': 1st reinforcing rod 2nd reinforcing rod 253: tightening wire
300: upside wire mesh

The present invention relates to a rectangular gabion, and in particular, each of the six wire mesh is combined in a box form with a hexagonal hexahedron, the tension control unit is installed in the inner space to prevent the phenomenon of full stomach generated when the stone is filled, It was installed on the banks of rivers and other surfaces to prevent flooding while preventing flooding.

Generally, stone-filled gabions are installed on the surface of slopes such as lakes and rivers to prevent the flooding of water and to prevent the slopes from being washed out by the water.

These gabions are formed so that they can be stacked in a vertical or horizontal direction by placing a plurality of stones therein, and is formed so as to form an opening in one side of the gabions, which is usually formed by a mesh having a cylindrical shape, to fill the stones therein. It is designed to close the opening with a lid after filling the stone.

However, the gabion having such a configuration has a lot of difficulty in filling the stone with the small size of the opening, and the workability becomes low in the process of binding the lid for blocking the opening with a separate iron wire after filling the stone. There was another problem.

In order to solve this problem, the raft gabion which is easy to fill the stone of Korean Utility Model Publication No. 20-342331 (2004.2.6) has been proposed, and the proposed raft gabion has a long direction from one end to the other end of the cylindrical mesh. An incision is formed and an incision with a predetermined distance is formed on both sides of the incision to facilitate stone filling. However, since the mesh is formed in a cylindrical shape, the gabion cannot be stacked in the vertical direction, and when it is constructed in the vertical direction, it is filled. Along with the cause of the phenomenon, there was another problem that was not parallel with other neighboring nets.

On the other hand, if the gabions are to be stacked vertically, there was another problem of inhibiting the aesthetics of the surroundings in the process of constructing the so-called Ashiba made of a separate horizontal or vertical pipe exposed to the front.

The present invention has been created to solve this problem, each of the six wire mesh is combined in the form of a six-sided box, the tension control unit is installed in the space provided therein is a phenomenon that occurs in the state filled with stones Its purpose is to provide a rectangular gabion that can be prevented from being cut while preventing flooding by installing it on a river shore or other surface of the river.

The present invention for achieving the above object is coupled to the four side wire mesh 200 in the form of a box on the edge of the bottom wire mesh 100, the upside wire mesh 300 is coupled to the upper side of the side wire mesh 200 The bottom wire mesh 100, the side wire mesh 200 and the upside wire mesh 300 are formed in a rectangular gabion (A) in which each wire 211 is formed in a lattice shape at a predetermined pitch (p) in the horizontal and vertical directions. ,
The side wire mesh 200 has a front wire mesh 210 and a rear wire mesh 220 on the front and rear, respectively, and the left wire mesh 230 and the light wire mesh 240 between the front wire mesh 210 and the rear wire mesh 220. ) Is configured, each of the vertical wires 211 constituting the front wire mesh 210 is bent toward the rear wire mesh 220 in a curved shape in the front wire mesh 210, the first seating portion 251 Is formed at least one and each of the vertical wire 221 constituting the rear wire mesh 220 is bent toward the front wire mesh 210 in the rear wire mesh 220 is bent in the first seating portion ( One or more second seating portions 251 ′ are formed to correspond to 251, and a first reinforcing rod 252 is inserted into the first seating portion 251, and the second seating portions 251 ′. The second reinforcing rod 252 'is inserted into, and the plurality of tightening wires 253 are twisted several times to the first reinforcing rod 252 and the second reinforcing rod 252'. Tensioning arm 250 which is tied to the features to be installed so as to pull the center.

In addition, the tension control unit 250 is composed of a plurality of tightening wire 253 is twisted several times, each of the wire wires 211 constituting the front wire mesh 210 is curved toward the rear wire mesh 220 At least one first seating portion 251 bent to form a second seating portion bent in a curved shape toward the front wire mesh 210 on each wire 221 constituting the rear wire mesh 220 One or more 251 'is formed, and a first reinforcing bar 252 and a second reinforcing bar 252' are inserted into the first seating part 251 and the second seating part 251 ', respectively. The tension adjusting unit 250 is installed on the reinforcing rod 252 and the second reinforcing rod 252 ', and the tightening wire 253 of the tension adjusting unit 250 is the first reinforcing rod ( 252) and the second reinforcing rods 252 '), and the bundled tightening wire 253 is twisted several times in the middle to be configured to pull the front blue network 210 and the rear wire mesh 211 toward the center. .

In addition, the first seat 251 of the front wire mesh 210 is formed to have a horizontal direction in the upper, lower and center, the second seat 251 ′ of the rear wire mesh 220 is the first Characterized in that it is formed to be symmetrical with the seating portion (251).

In addition, the bottom wire mesh 100, the side wire mesh 200 and the edge where the upside wire mesh is coupled by the binding wire 400, the binding wire 400 is formed to have the form of a spring twisted spirally. It is characterized by.

And the pitch (p) of the binding wire 400 is formed the same as the pitch (p) of the wire wire 211 of the bottom wire mesh 100, the side wire mesh 200 and the upside wire mesh 300, the binding wire ( One end of one side of the 400 is achieved to provide a rectangular gabion, characterized in that it is formed to have a twisted shape out.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

The gabion (A) according to the present invention is composed of a bottom wire mesh 100, a side wire mesh 200, an upside wire mesh 300 and a binding wire 400 as shown in Figs.

Here, each of the bottom wire mesh 100 is composed of a plurality of wire wires 211 cut to a predetermined length such that the side wire mesh 200 is coupled to the edge while supporting the stone (rubble) to be described later. It is formed in the shape of a rectangular box, and the wire mesh 211 of the square is formed in a lattice shape at a predetermined pitch p by being joined by spot welding so that the other wire 211 crosses the inside of the rectangular border. It is configured to have.

In addition, in the side wire mesh 200 and the upside wire mesh 300 of the bottom wire mesh 100, some horizontal and vertical wire 211 pitch p is configured to be narrower than the pitch p of other wire 211. It is configured to increase the partial strength.

The side wire mesh 200 is coupled to the bottom edge of the bottom wire mesh 100 is formed in a vertical form, each of the corners formed in the vertical form by combining the binding wire 400 to have an open top box shape. The front wire mesh 210, the rear wire mesh 220, the left wire mesh 230, and the light wire mesh 240 are configured on the basis of the front, rear, left, and right sides of the bottom wire mesh 100.

The front wire mesh 210 has the same shape as the bottom wire mesh 100 and has at least one first seating portion 251 having a tension adjusting part 250 to be described later.

The first seating portion 251 is bent to protrude in a curved form toward the rear wire mesh 220 on each of the wires 211 constituting the front wire mesh 210 to the first seating portion 251 The first reinforcing bar 252 is configured to be fitted from the outside.

The first seat 251 is preferably to be bent in the shape of a bent, not to form a front wire mesh 210 by bending one wire (211) in a shape of a bend to allow a length to be bent in a shape of a bend. It is preferable to manufacture the same as the shape of the bottom wire mesh 100 so as to be molded toward the other end from one end of the front wire mesh 210 at a time using a press or the like.

In addition, the first seat 251 is more preferably formed to have a horizontal direction in the upper, lower and center, respectively.

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The rear wire mesh 220 is formed in the same shape as the front wire mesh 210, and each of the vertical wires 221 constituting the rear wire mesh 220 is bent toward the front wire mesh 210 in a curved shape. One or more parts 251 'are configured to be formed, and the second reinforcing rod 252 is configured to be externally fitted to the second seating part 251'.

In addition, the rear wire mesh 220 is configured to have the same shape as the front wire mesh 210.

The left wire mesh 230 and the light wire mesh 240 are coupled with the binding wire 400 between the top of the bottom wire mesh 100 and the front wire mesh 210 and the rear wire mesh 220 by the bottom wire mesh 100. It is configured to have the same form as.

The tension control unit 250 is a stone therein so that a certain amount of tension is always applied to the front wire mesh 210 and the rear wire mesh 220 coupled to be perpendicular or perpendicular to the top at the edge of the bottom wire mesh 100. To prevent the occurrence of full stomach phenomena when filled, when the gabions are stacked vertically or continuously in the horizontal direction, the same direction as other neighboring gabions, that is, vertical or horizontal direction, is provided. Consists of.

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The first reinforcing rod 252 and the second reinforcing rod 252 'is a steel rod having a predetermined diameter, the length of which is equal to the length of each of the first and second seating portions 251 and 251' to be seated. In some cases, the length of the first and second reinforcing rods 252 and 252 'is made longer so that the first and second reinforcing rods 252 and 252' are allowed to rest on the other first and second seating portions formed in the neighboring gabions A '. However, it is more desirable to be able to fit the vertical form.

The tightening wire 253 of the tension adjusting unit 250 is the first reinforcing rods 252 and the second reinforcing rods 252 ′ fixed to each other by being tied or wound at both ends by compression tension thereof. Direction, that is, a pull phenomenon in which the front wire mesh 210 or the rear wire mesh 220 protrudes outward by the pressure of the stone 500 which is pulled in the inner direction of the gabion A and filled in the gabion A. It is configured to be prevented.

To this end, the fastening wire 253 is both sides of each of the first reinforcing rods 252 and the second reinforcing rods 252 'seated on the first seating portion 251 and the second seating portion 251'. It is preferable that the ends are bundled, and the parts to be bundled are tied at a portion where the pitch p of the wires 211 constituting each of the front wire meshes 210 and the rear wire meshes 220 becomes narrower.

At this time, the remaining portions are bundled by using a separate bundle wire 254 having a short length, so that all the first seating portions 251 and the second seating portions 251 'are respectively the first reinforcing rods 252 and the second. It is tied to the reinforcing rods (252 ') to prevent the lifting.

In addition, the tightening wire 253 of the tension control unit 250 is tied to have a shape of an oval or closed curve in the state in which a screwdriver or a small rod is inserted in the center to rotate the tightening wire 253 is twisted both sides thereof The first reinforcing rods 252 and the second reinforcing rods 252 ′ tied to each other are configured to be pulled to the center.

One example of such a tension control unit 250, but a plurality of the tension adjusting unit 250 to match the number of the first seating portion 251 formed on the front wire mesh 210 or the second seating portion 251 'formed on the rear wire mesh 220. It is desirable to be able to use it.

Meanwhile, in the present invention, the first seating portion 251 formed on the front wire mesh 210 and the second seating portion 251 ′ formed on the rear wire mesh 220 have a horizontal shape. The 210 and the rear wire mesh 220 may be formed to have a vertical shape by rotating 90 °.

The upside wire mesh 300 is filled with the stone 500 by filling the stone 500 in the inner space of the box-shaped gabion open at the top by the combination of the bottom wire mesh 100 and the side wire mesh 200 ) Is configured to have the same shape as the bottom wire mesh 100 to be coupled to the upper portion of the side wire mesh 200 to prevent it from exiting to the outside, the upside wire mesh 300 is at the top of the side wire mesh 200 It is configured to be combined.

The binding wire 400 binds the edges of the plurality of bottom wire mesh 100, the side wire mesh 200, and the upside wire mesh 300 to form a gabion, respectively, and the shape is formed to have a spring shape twisted in a spiral shape. The lower end of the binding wire 400 is to be inserted into a mesh having a rectangular shape on the upper side in a state where the front end of the binding wire 400 is in contact with the front wire 210 and the left wire mesh 230. Then, as soon as the hand is released and rotated in a spiral direction by moving downward by its own weight, the binding wire 400 is bound in a thread-like form between one mesh connected vertically.

The pitch p of the binding wire 400 is preferably formed to have the same pitch as the pitch p of the wire wire 211 of the wire mesh to be joined or fitted, respectively, the lower end of the binding wire 400 Its end is formed to have a shape twisted out.

When the bottom end of the binding wire 400 is not open, the end of the binding wire 400 is in contact with each iron wire that is positioned in the vertical or horizontal form in the process of falling downward by the weight of the binding wire 400. It is configured to prevent twisting and non-binding. That is, even though the edge portion to enter the center of the binding wire 400 is slightly twisted in the process of moving as if falling down with a certain flow interval, the twisted portion is guided while being pulled toward the center by the portion spread outward. As it becomes possible to be easily bound.

Square gabion having such a configuration, first, the bottom of the bottom wire mesh 100 and the front wire mesh 210 by setting the bottom wire mesh 100 in a state in which the front wire mesh 210, which is one of the side wire meshes 200, is placed on the floor. The edges of the abutment, and the lower end of the binding wire 400 is fitted in the corners abutting each other and then the binding wire 400 and at the same time the binding wire 400 moves downward by its own weight and at the same time Helical penetrates through each of the nets and is bound in a threaded state.

Next, after the bottom of the binding wire 400 is stopped by touching the bottom, the binding wire 400 is reversed even if the bottom wire mesh 100 and the front wire mesh 210 are turned upside down by pinching the upper portion of the binding wire 400. It will prevent you from falling out.

Next, the front wire mesh 210, the rear wire mesh 220, the left wire mesh 230, and the light wire mesh 240 are coupled to the bottom wire mesh 100 by repeating the above process.

Next, after inserting the first reinforcing rod 252 into the first seating portion 251 formed to face the rear from the front of the front wire mesh 210, the portion of the narrow wire spacing in contact with the first reinforcing rod 252 All parts except the bundle wires 254 are fixed and bundled, the second reinforcing bar 252 'is inserted into the second seating portion 251' formed in the rear wire mesh 220, and then the bundle wires 254 are inserted. Tie and fix.

Next, both sides of the tightening wire 253 of the tension adjusting unit 250 is wrapped in each of the first reinforcing bar 252 and the second reinforcing bar 252 'fixed by the bundled wire 254. Winding, and by inserting a screwdriver, etc. in the center of the rotation, the tightening wire 253 is twisted while pulling the first reinforcing rods 252 and the second reinforcing rods 252 'on both sides thereof.

Next, the first reinforcing rods 252 and the second reinforcing rods 252 'are pulled by the tightening wire 253 of the tension adjusting unit 250 to fill the stone 500 into the gabion formed in the box shape and To cover the upside wire mesh 300 on top of the side wire mesh 200 is filled with stone 500 it is possible to obtain a single gabion (A).

In the present invention, the process of obtaining a single gabion (A) has been described, but when constructing it continuously in a horizontal direction, such as a river raft or slope using the gabion (A), the first reinforcing rod 252 and the second reinforcement As the length of the rod 252 'is lengthened, as shown in FIG. 6, another gabion A' is further added to the front and rear surfaces by being inserted into each of the seating portions formed in the two front panels or the two rear panels. It can prevent protruding or sinking.

In addition, as shown in FIG. 7, when the gabion A is vertically stacked on a roughly vertical arc or inclined surface 600, all of the seating portions formed on each front panel or rear panel face each other vertically. As described above, a long reinforcing rod can be used to prevent any one of the gabions from protruding and sinking.

On the other hand, as shown in Figure 8 can be used to have a shape of the retaining wall by stacking the rectangular gabion (A) in the vertical direction, in this case, the length of the gabion stacked from the top of the gabion located at the bottom sequentially It can be shortened and stable to use.

In the present invention, the bottom wire mesh 100, the front wire mesh 210, the rear wire mesh 220, the left wire mesh 230, the light wire mesh 240 and the upside wire mesh 300 forming a rectangular gabion have been described to have a box shape. As shown in FIG. 9, the bottom wire mesh 100 having the front wire mesh 210 and the rear wire mesh 220 having a long rectangular shape and being bound to the front wire mesh 210 and the rear wire mesh 220, respectively. When the left wire mesh 230, the light wire mesh 240, and the upside wire mesh 300 fit the length thereof, they have a mattress shape so that they can be easily cut and laid on a sloping lake or a slope 700 having a gentle inclination angle. It can be prevented.

As described above, the present invention is formed in a rectangular box shape by a wire mesh in which the iron wires are formed in a lattice shape at a predetermined pitch in a horizontal and vertical direction, and a tension control unit is installed therein to fill the stone to be installed on a lake or slope. In addition, it is possible to prevent partial filling phenomenon occurring in the gabions, and to prevent the neighboring gabions from protruding or sinking by the reinforcing rod. In addition, the construction is installed on the shore of the river or other surface to prevent flooding while preventing flooding.

Claims (6)

delete Four side wire mesh 200 is coupled to the edge of the bottom wire mesh 100 in the form of a box, the upside wire mesh 300 is coupled to the top of the side wire mesh 200, the bottom wire mesh 100, the side The wire mesh 200 and the upside wire mesh 300 are formed in a rectangular gabion A in which each wire 211 is formed in a lattice shape at a predetermined pitch p in a horizontal and vertical direction. The side wire mesh 200 has a front wire mesh 210 and a rear wire mesh 220 on the front and rear, respectively, and the left wire mesh 230 and the light wire mesh 240 between the front wire mesh 210 and the rear wire mesh 220. ) Is configured, each of the vertical wires 211 constituting the front wire mesh 210 is bent toward the rear wire mesh 220 in a curved shape in the front wire mesh 210, the first seating portion 251 Is formed at least one and each of the vertical wire 221 constituting the rear wire mesh 220 is bent toward the front wire mesh 210 in the rear wire mesh 220 is bent in the first seating portion ( One or more second seating portions 251 ′ are formed to correspond to 251, and a first reinforcing rod 252 is inserted into the first seating portion 251, and the second seating portions 251 ′. The second reinforcing rod 252 'is inserted into, and the plurality of tightening wires 253 are twisted several times to the first reinforcing rod 252 and the second reinforcing rod 252'. Rectangular tensioning arm 250 which is tied, characterized to be installed so as to pull the center gabion. delete The method of claim 2, Each bottom edge of the bottom wire mesh 100, the side wire mesh 200 and the upside wire mesh 300 are joined by a binding wire 400 twisted in a spiral shape. The method of claim 4, wherein The pitch p of the binding wire 400 is formed to be the same as the pitch p of the wire 211 of the bottom wire mesh 100, the side wire mesh 200 and the upside wire mesh 300, and the binding wire 400 One end of the gabion is characterized in that it is formed to have a twisted form out. The method according to claim 2 or 4, In the bottom wire mesh 100, the side wire mesh 200 and the upside wire mesh 300, the pitch (p) of some wires 211 is characterized in that the narrower than the pitch (p) of the other wires 211 gabion.

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