KR101647433B1 - A protective wall capable of planting - Google Patents

Abstract

The present invention relates to a protective wall which is stored in a folded state, is used as a protective wall for vegetation after filling soil in an unfolded state for installation, facilitates connection regardless of an angle formed by two neighboring unit protective walls, and conveniently dismantles contents. The unit protective wall comprises: a pair of side wire nets (10) which face each other and are separated from each other; a pair of joint wire nets (20) connecting both ends of the side wire nets facing each other to regulate a joint surface of a space divided by the side wire nets; a bottom wire net (30) connected to lower ends of the side wire nets or lower ends of the joint wire nets to regulate a bottom surface of a space divided by the side wire nets and the joint wire nets; a connection member (50) inserted into ends of two wire nets to be connected on a connection portion of the wire nets (10, 20, 30) to allow the two wire nets connected on the connection portion of the wire nets (10, 20, 30) to pivot on each other; and geotextile (70) to cover inner surfaces of the side wire nets, the joint wire nets, and the bottom wire net to store contents (80) in a space regulated by the side wire nets, the joint wire nets, and the bottom wire net.

Description

{PROTECTIVE WALL CAPABLE OF PLANTING}

The present invention relates to a barrier wall, more particularly, it can be stored in a folded state, can be used as a vegetation barrier after filling the gravel in an expanded state for construction, and is easy to connect regardless of the angle between adjacent two unit barriers And to easily dismantle the contents.

The barrier is a civil structure that is installed in the middle of the road, on the nodular shoulder of the road, in the railings of the bridge, to prevent the vehicle from falling off the road or falling off the road.

Because the barrier wall must be able to absorb the momentum of a high speed, high load vehicle, various types of firewalls are used, such as block concrete, metal panels, PE barrier that can store a large amount of water inside, The road environment at the point where the barrier is to be installed, and the like.

However, concrete block type firewalls are effective in preventing the vehicle from escaping, but it is inadequate to absorb the impact of the vehicle and to prevent injuries to the vehicle occupant. Also, guide rails and barrier walls made of metal panels have a low shock absorbing rate, and when a vehicle is hit, an accident occurs that the metal panel penetrates into the vehicle and leads to the passenger's death.

The PE barrier, which stores water, is used for temporary purposes because of its low impact absorption rate and its effect on prevention of vehicle departure.

In addition, since the above-described barrier walls are all constructed in such a way that they can not be vegetated, there has been a problem in that the roads with poor feelings are further deserted.

Patent Registration No. 1391459

Disclosure of the Invention The present invention has been conceived to solve the problems described above. It is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide a vehicle having a high impact absorption rate, The present invention relates to a fire wall structure that can be used as a fire wall.

In order to solve the above-described problems, the present invention provides a pneumatic tire comprising: a pair of side wire nettings (10) facing each other and spaced apart; A pair of joint surface wire meshes (20) connecting the opposing ends of the pair of side surface mesh wires to each other to define a joint surface of a space defined by the pair of side surface mesh wires; A bottom wall connected to a lower end of the pair of side wall wires or connected to a lower end of the pair of side wall walls to define a bottom surface of the space defined by the pair of side wall wires and the pair of splice- A cotton wire net 30; 20 and 30 are pivotally connected to each other at a connection portion of the wire meshes 10, 20 and 30, ; And a pair of side walls, a pair of side walls, a pair of side walls, a pair of side walls, a pair of side walls, And a geosynthetic fiber (70) covering the inner surface of the wire mesh.

A connecting member may be further inserted in a vertical direction at an intermediate portion of the joint network 20.

In order to prevent the pair of side wire nettings 10 from bulging out due to the contents, the middle side portions of the pair of side wire nettings 10, which are disposed between the pair of side wire nettings 10, And a supporting member for connecting the supporting member.

At least one of the connecting members fitted to the end portions of the two wire meshes to be connected is formed of a spring-shaped wire 51 inserted along the connecting portion of one wire net, a spring-shaped wire 51), and a straight wire (52) which is inserted in the longitudinal direction after superimposing the two spring-like wires.

One of the connecting members fitted to the ends of the two wire meshes to be connected is connected to the one spiral release wire 61,

The spiral wire 61 for pulling-off is rotatably supported at one end thereof with the substantial longitudinal direction of the spiral wire as a rotation axis, and as the wire is pulled in the longitudinal direction, It rotates along the shape and comes out.

The spiral wire 61 for drawing release has an inner diameter d of 20 to 35 mm and a wire l of 60 to 105 mm and a wire tensile strength of 390 to 780 N / mm ² .

The spiral wire 61 for drawing release may have a ring part 62 formed at at least one end thereof.

The above geoscientific fibers can be compression-coated with a polyurethane film to prevent the loosening of geosynthetic fibers.

Further, in order to solve the above-mentioned problems, the present invention is characterized in that the connecting members of the unit barrier walls are connected to each other by a connecting wire, And a linear wire 52 is inserted into the wire 51 along the longitudinal direction thereof to connect the two or more unitary walls.

Further, in order to solve the above-mentioned problems, the present invention provides a barrier wall including a plurality of barrier ribs 920 disposed at least facing each other and side walls 930 connecting side faces between the facing barrier ribs 920, The side wall 930 includes two or more divided side walls 931 and 932 and a space surrounded by the side walls 930 connecting the side walls 920 and the side walls 920 is a partition space s, The partition space s is adjusted in its shape by overlapping or separating the partition walls 920 facing each other and a connection portion between the side wall 930 and the partition wall 920 and between the adjacent two divided side walls 931 and 932, And at least one of the connecting members 50 provided between the side wall 930 and the partition wall 920 constituting the one compartment space s and between the two divided side walls 931 and 932 adjacent to each other, (60), wherein the simple connection coupling member 60 includes a spiral wire 61 for releasing the spiral wire 61. The spiral wire 61 for releasably rotatably supports one end of the spiral wire with the substantial longitudinal direction of the spiral wire as a rotation axis, Upon pulling, the wire mesh to be connected and the wound portion provide a barrier wall that rotates and exits along the shape of the spiral.

Further, in order to solve the above-mentioned problems, the present invention provides a barrier wall including a plurality of barrier ribs 920 disposed at least facing each other and side walls 930 connecting side faces between the facing barrier ribs 920, The side wall 930 includes two or more divided side walls 931 and 932 and a space surrounded by the side walls 930 connecting the side walls 920 and the side walls 920 is a partition space s, The partition space s is shaped by overlapping or separating the partition walls 920 facing each other and a bottom wall 940 including two or more divided bottom walls 941 and 942 is formed at the lower end of the facing partition wall 920 And a connection is made between the side wall 930 and the partition wall 920, the adjacent two divided side walls 931 and 932, the connection between the bottom wall 940 and the partition wall 920 and the adjacent two divided bottom walls 941 and 942 And a side wall 93 constituting one compartment space s At least one of the connecting members provided between the partition wall 920 and the bottom wall 940 and the partition wall 920, the adjacent two divided side walls 931 and 932 and the adjacent two divided bottom walls 941 and 942, (60), wherein the simple connection formulating member (60) comprises a spiral wire (61) for drawing release and the spiral wire (61) for drawing release has one end of the spiral wire And rotatably supported by a rotating shaft, and pulled in a longitudinal direction, thereby providing a barrier wall in which wire meshes to be connected and a coiled portion are rotated and released along the shape of the spiral.

The inner diameter d of the spiral wire 61 is 20 to 35 mm and the lead 1 of the spiral wire is 60 to 105 mm and the tensile strength of the wire is 390 to 780 N / mm ² .

The simple connection form coupling member 60b includes one partition wall 920 for partitioning the two partition spaces s2 and s3 and two divided partition walls 932 and 931 facing one end of the partition wall 920 It is possible to easily open the two compartments S2 and S3 when the form coupling member 60b is released.

The geosynthetic fiber is sandwiched in the compartment space (s), and the geosynthetic fiber is press-coated with a polyurethane film to prevent the loosening of the geosynthetic fiber.

Further, in order to solve the above-described problems, the present invention is characterized in that, at the connection portions of the walls (920, 930, 931, 932, 940, 941, 942) of the wire netting (10, 20, 30) A spiral wire (61) for releasing a pull-out as far as possible, characterized in that the spiral wire (61) for pulling-out is rotatably supported at one end thereof with a substantial longitudinal direction of the spiral wire as a rotation axis, The wire mesh and the wound portion to be spirally wound are released in the form of a spiral.

The inner diameter d of the spiral wire 61 is 20 to 35 mm and the lead 1 of the spiral wire is 60 to 105 mm and the tensile strength of the wire is 390 to 780 N / mm ² .

The spiral wire 61 for drawing release may have a ring part 62 formed at at least one end thereof.

Further, in order to solve the above-described problems, the present invention is characterized in that the present invention is characterized in that the spiral wire is provided between one end of the helical wire and the supply of the pulling force, and corresponds to the number of times of the helical winding of the spiral wire And a pull-out connection 64 that is free from twisting.

The pull-out connector 64 includes a hook 651 connected to the hook 62; A hook portion 652 located at the opposite portion of the hook portion; And a rotation hook 65 for connecting the hook 651 and the hook 652 so as to be rotatable with respect to the drawing shaft.

Further, in order to solve the above-mentioned problems, the present invention provides a method for separating a spiral wire for drawing-off 61 from a connection portion of a wall 920, 930, 931, 932, 940, 941, 942 of a wire net 10, 20, Connecting one side of the draw-off port (64) to one end of the helical wire and connecting the other side of the draw-off port to the supply of the pull-out force; Pulling out the supply portion of the pulling force in a direction in which the helical wire is to be pulled out; And a step of releasing the draw-off releasing spiral wire (61) by means of the pull-out connector as the pull-out portion of the pull-out force is pulled out and coming out from a connection portion between the wire-nettings .

According to the present invention, a barrier wall can be constructed using a unit barrier wall that is filled with the gravel and is capable of vegetation, thereby providing a cozy feeling on the roads that are washed away.

In addition, according to the present invention, it is possible to install the unit barrier as well as the straight line as well as the curved road very flexibly.

According to the present invention, when the fire wall is not used, the fire wall can be folded and stored, the transportation is easy, and the fire wall can be constructed by using the gravel near the site during the fire wall work in the field.

Further, according to the present invention, even when the barrier wall is dismantled, the inner soil can be emptied, thereby facilitating the dismantling work.

In addition, according to the present invention, the side walls or the bottom surface of the unit barrier wall can be easily opened at the time of disassembly, so that the operation of emptying the gravel can be carried out very easily. Especially, if you use the spiral wye for unscrewing, you can release the worker without help of heavy equipment, and work efficiency can be further increased.

The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

1 is a perspective view of a unit barrier according to the present invention,
FIG. 2 is an exploded perspective view of the unit barrier of FIG. 1,
3 is a view showing a state in which two neighboring wire meshes are connected by one spring-shaped wire,
4 is a view showing a state in which spring-shaped wires are connected to two neighboring wire meshes,
FIG. 5 is a view showing a state in which two wire meshes are connected by inserting a straight wire in a state where the two spring-shaped wires of FIG.
FIG. 6 is a perspective view showing a state in which geared fibers are inserted into the unit barrier of FIG. 1;
Fig. 7 is a developed view of the geo-fiber of Fig. 6,
FIG. 8 is a plan view showing two unit security walls, showing a state before joining seams of the unit security walls,
FIGS. 9 to 11 are views showing various forms of connecting adjacent unitary walls of FIG.
12 is a side view showing a state in which a unit barrier wall containing a gravel is lifted by using a heavy equipment such as a crane,
FIG. 13 is a side view illustrating a state in which the bottom connecting wire network is opened by releasing the easy connection connecting member connected to one side of the bottom side wire net of the unit barrier of FIG. 12;
FIG. 14 is a front view and a side view of a spiral wire as another embodiment of the simple connection formulating member of the present invention,
15 is a view showing a state in which two wire nets are connected by the helical wire of Fig. 14, Fig.
FIG. 16 is a view showing a state where a drawing connector is connected to a loop of the helical wire of FIG. 15;
17 is a view showing a process in which a helical wire is pulled out from a two-wire net by pulling out a draw-
FIG. 18 is a view showing a spiral wire taken out from a two-wire net as shown in FIG. 17,
FIG. 19 is a perspective view showing a state of use of a folding type fire wall capable of applying the simple type coupling member according to the present invention; FIG.
Fig. 20 is a front view showing a state in which the barrier wall of Fig. 19 is folded in half,
Figure 21 is a bottom view of the barrier of Figure 20, and
22 is a plan view of the barrier wall of Fig. 19 viewed from above.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to inform.

[Unit Firewall]

FIG. 1 is a perspective view of a unit barrier according to the present invention, FIG. 2 is an exploded perspective view of the unit barrier shown in FIG. 1, FIG. 3 is a view showing a state where two neighboring two- And FIG. 5 is a view showing a state in which two wires are connected by inserting a straight wire in a state where the two spring-shaped wires of FIG. 4 are overlapped.

1 and 2, the unit barrier of the present invention includes a side wire net 10 constituting two long sides in a rectangular parallelepiped shape, a seam side wire net 20 constituting short two side faces in a rectangular parallelepiped shape, And a bottom surface wire net 30 constituting a surface.

The neighboring wire meshes (10, 20, 30) are connected by a connecting member (50) pivotally connecting adjacent two wire meshes. As one example, the connecting member 50 may be one spring-shaped wire 51. As another example, the connecting member 50 may be two spring-shaped wires 51 and a straight wire 52. As another example, the connecting member may be a simple connection forming member 60 or a spiral release wire 61 which will be described later.

One spring-shaped wire 51 is inserted and connected to the four corners where the side wire net 10 and the joint side wire net 20 are connected to each other. That is, as shown in FIG. 3, when two corners of the two wire meshes are shared by one spring-shaped wire 51, two neighboring wire meshes are pivotally connected to each other.

As shown in FIGS. 1 and 2, the bottom side wire netting 30 is connected to the side edge portions of the side wire netting 10 by connecting members 50. Alternatively, it is of course possible that the bottom edge wire net 30 is connected to the two edge portions adjacent to the splice edge mesh 20 by the connecting member 50. In the embodiment of the present invention, a structure in which the bottom side wire netting 30 is connected to the side wire netting 10 is illustrated. One end portion of the bottom side wire netting 30 is connected to the side wire netting 10 through one spring-like wire 51.

The other end of the bottom wire netting 30 is releasably connected using two spring-like wires 51 and a straight wire 52. 2 and 4, a spring-shaped wire 51 is fitted to the other end of the bottom side wire netting 30 and the lower end of the side side wire netting 10 facing each other. Then, as shown in Figs. 2 and 5, after the two spring-shaped wires are superimposed, the straight wire 52 is fitted.

As shown in FIG. 5, when the two wire nets are pivotally connected, the connection of the two wire nets can be easily released only by removing the straight wire 52 from the overlapped spring wire later. That is, when the two wire nets are connected by one spring-like wire 51 as shown in Fig. 3, the connection of the two wire nets can not be released unless the spring-shaped wire 51 is rotated one by one. As shown in the drawing, when two wire meshes are connected by two spring-shaped wires and a straight wire 52, the connection of the two wire meshes can be easily released simply by pulling out the straight wire 52. In particular, in a state where the contents 80 are filled in the wire mesh, the two wire meshes are pressed in the direction in which they are widened. Therefore, when the two wire meshes are connected as shown in FIG. If two wires are connected as shown in FIG. 5, it is possible to disconnect the two wires even when the contents 80 are filled.

1 and 2, the intermediate portions of the two side wall meshes 10 are connected to each other by the supporting mesh net 40. [ Since the side wall 10 is longer than the side wall 20, when the contents 80 are filled in the inside, the middle portion of the side wall 10 protrudes outward convexly. do. However, if the middle portion of the two side wire nettings 10 is connected to the supporting wire netting 40 as shown in the drawing, such an overlaying phenomenon can be prevented. Both end portions of the supporting wire net 40 are bound together through the wire in the middle portion of the two side wire nettings 10 and the spring-like wire 51. That is, the intermediate portion of the side wall 10 and the supporting wall 40 are also pivotably connected.

As described above, when the other end of the bottom wire net 30 and the lower end of the side wire net 10 are releasably connected using the two spring-shaped wires 51 and the straight wire 52, Both of the four corner portions where the connecting wire 10 and the connecting wall 20 are connected to each other and the two portions where the supporting wire net 40 is connected to the middle portion of the side wire net 10 are pivotally connected The unit barrier can be folded flat. The flattening of the unit barrier walls is possible even in a state in which a flexible geosynthetic fiber 70 to be described later is inserted into the wire mesh structure of the unit barrier wall to contain the contents.

On the other hand, as shown in FIGS. 1 and 2, a spring-shaped wire 51 is interposed in the middle of the jointed-wire network 20. As will be described later, the spring-shaped wire 51 inserted in the middle of the joint network 20 is used together with the straight wire 52 when unit walls are connected to each other.

In the embodiment of the present invention shown in FIGS. 1 and 2, a bottom wire net 30 is formed of a single wire net. However, the structure in which the bottom side wire netting 30 is divided into two parts based on the supporting wire netting 40 described above is also applicable. Although not shown in the figure, two neighboring portions of two bottom side wire nettings and a lower end portion of the supporting netting wire 40 are connected by one spring-like wire 51, and two bottom- It is of course possible to releasably connect the opposite end portion and the lower end portion of the diaphragm wire net 20 to each of the two spring-like wires 51 and one straight wire 52 as shown in FIG.

1 and 2, a structure in which the other end of the bottom surface wire net 30 is releasably connected to the two spring-like wires 51 and one straight wire 52 is shown have. However, it is of course possible to apply a releasably connected structure to other connection portions between the wire meshes 10, 20, 30, and 40 as needed.

Also, the structure in which two wire meshes are releasably pivotally connected is not limited to the structures shown in Figs. 4 and 5, and two or more wire meshes can be released by other structures as shown in Figs. 14 to 18 Of course, be pivotable.

[Geo fiber]

FIG. 6 is a perspective view showing a state in which geared fibers are inserted into the unit barrier wall of FIG. 1, and FIG. 7 is an exploded view of the geo-fiber in FIG.

As shown in FIG. 7, when the geoscientific fibers are cut and folded inward or outward, the geosynthetic fibers can be inserted into the wire net structure of the unit barrier wall as shown in FIG. 7, the geosynthetic fiber 70 has an inner side contact portion 72, a side side wire meshing inner side contact portion 71, a supporting wire meshing inner side contacting portion 74, a bottom side wire meshing inner side contacting portion 74 and an outer side overlap portion 79, respectively, which are in contact with the inside of the corresponding wire mesh. At this time, the outer overlapped portion 79, which is the outer overlapping portion of the top overlapping portion of the geoscientific fiber, is fitted so as to be in contact with the outer surface of the wire mesh, and then it can be sealed with a ground fiber portion overlapped on the inner side with a stapler. The three-part ground wire mesh inner contact portions 74 are superposed one on top of another to form a bottom surface.

The geosynthetic fiber is made of a polyester material, and the surface of the geosynthetic fiber is coated with a polyurethane film. Since the polyurethane has good water permeability, even when the polyurethane film is squeezed, the permeability remains almost unchanged. In particular, since the polyurethane is melt-bonded to the polyester fiber of the geosynthetic fiber, it is possible to prevent the polyester from loosening. Particularly, in the case of a barrier wall installed around the road and installed for a rescue, if the water level of a nearby charge or sea is increased or a storm is generated and the barrier wall is frequently exposed to water, Reinforcing the geosynthetic fiber can prevent the geosynthetic fibers from coming loose.

A safety indicator 78 may be provided on the outer surface of the geosynthetic fiber visible through the side wall 10 so as to be recognized as a barrier wall.

After the geosynthetic fibers 70 have been applied to the inside of the unit barrier wall, the soil 80 can be filled with the soil 80, and the thus filled soil can be vegetated.

Unit firewalls are filled with soil and field vegetation. It may be different depending on the situation of the work site. However, it is possible to move the unit barrier by using a crane or the like in a state where the contents are filled in the unit barrier wall, and place the unit barrier at a desired position, It is also possible to fill the soil with vegetation.

[Building a Unit Firewall]

FIG. 8 is a plan view showing two unit security walls, and is a view showing a state before connecting the joint surfaces of the unit barrier walls. FIGS. 9 to 11 are views showing various forms of connecting the adjacent unitary walls of FIG. to be.

When a unit barrier is installed at a desired installation position, the unit barrier walls are arranged along the longitudinal direction of the road and then connected to each other. As shown in FIG. 8, a pair of spring-shaped wires 51 face each other at three portions (a, b, c) of the joint wall 20 of the two unitary bridges adjacent to each other.

In a state where the contents are filled in the unit barrier wall, as shown in FIG. 9, the joint surface wire mesh 20 also causes a call-up phenomenon. Accordingly, when connecting two adjacent unitary walls in a straight line, the two spring-shaped wires 51 in the middle portion b of the diaphragm wire 20 are overlapped with each other and the straight wire 52 is inserted (see FIG. 5) As shown in FIG. 9, the two unitary walls are connected to each other.

On the other hand, when the barrier wall is installed in the curved section, the two spring-shaped wires 51 at the end portion (a or c) are overlapped with each other and the straight wire 52 is inserted, It is possible to connect the firewalls to each other and arrange the unit firewalls according to the curve section.

According to the present invention, it is possible to construct a barrier wall which can be flexibly applied to a straight or curved section.

[Demolition of fire wall]

FIG. 12 is a side view illustrating a state in which a unit barrier wall containing a gravel is lifted by using a heavy equipment such as a crane, FIG. 13 is a cross-sectional view of the unit barrier wall of FIG. And a bottom surface wire net is opened.

When it is necessary to dismantle the firewall, first, the connection between the unit firewalls shown in Figs. 9 to 11 is released. This can be easily accomplished simply by pulling out the straight wire 52 inserted in a state in which the two spring-shaped wires 51 provided on the jointed-wire network 20 of the neighboring two unitary walls are overlapped.

Next, a heavy equipment such as a crane is used to lift and move a unit barrier that is disconnected from neighboring unit firewalls. The unit barrier wall is moved to a predetermined position and then the unit barrier is lifted by a crane so that the unit barrier wall is releasably connected between the other end of the bottom surface wire net 30 and the lower end of the side wire net 10, (Which can be achieved by pulling out the straight wire 52), the bottom surface wire net 30 is opened downward as shown in FIG. 13, and the soil contained in the inside is easily poured It is possible to pay. 6 and 7, the top overlapping portion of the geoscientific fibers 70 is fixed to the wire netting, and the inner side contact portions of the bottom side wire netting are simply supported by the bottom wire netting in a state of being superimposed on each other, At the moment when the wire mesh is opened, the geosynthetic fiber (70) is pushed out of the inner contents only while it is attached to the wire mesh.

After clearing the contents, you can lower the unit barrier from the crane, fold the unit barrier flat and store it in the warehouse.

Although the simple connection coupling member illustrated above is connected between the other end of the bottom wire net 30 and the lower end of the side wire net 10, And may be used between the joint surface wire mesh 20 and the bottom surface wire mesh 30 or between the joint surface wire mesh 20 and the side wire mesh 10.

[Simplified form connection member]

The releasably connected connecting member described above was installed and unlocked in such a manner that the two spring-shaped wires were overlapped and a straight wire was inserted or pulled thereon. However, in such a connection method, when connecting three or more wire nettings at the same time, it is difficult to superimpose three or more spring-shaped wires, which makes it difficult to use. In addition, since this type of connection structure has a structure in which two or more spring-shaped wires are overlapped, the portion may not be superimposed when it is folded flat and stored in a warehouse. According to another aspect of the present invention, there is provided a simple form coupling member (60) that is easy to install and disassemble even with only one wire structure.

Fig. 14 is a front view and a side view of a spiral wire according to another embodiment of the present invention. Fig. 15 is a view showing a state in which two wire meshes are connected to each other by helical wires of Fig. And FIG. 17 is a view showing a process in which a helical wire is pulled out from a two-wire net by pulling out the draw-out connector of FIG. 16, and FIG. 18 is a view Fig. 3 is a view showing a pulled spiral wire.

The spiral wire 61 shown in Fig. 14 is formed such that the spiral wire 61 has a pitch or a lattice length l of the spiral relative to the inner diameter d of the spiral, as compared with the spring- very big.

To describe this in more detail, the above-mentioned general spring-shaped wire 51 has an inner diameter larger than the pitch or lead of the spring. This is a shape for preventing the spring-shaped wire 51 from falling out after itself is inserted into the wire netting.

On the other hand, the helical wire has about 2 to 5 times the pitch or lead (l) of the helix to the inner diameter (d) of the helix. At one end of the helical wire 61, a ring 62 is formed as shown. The annular portion 62 can be formed simply by deforming the end portion of the helical wire into a ring shape and then welding the end portion thereof. The ring portion 62 becomes a portion where the draw-off connector 64 is fixed as shown in Fig. 16 when the helical wire 61 is pulled out.

The helical wire 61 is a structure capable of pulling out the wire itself and releasing it. That is, when the helical wire 61 is pulled to one side by applying a force in a state where the hooking connector 64 is connected to the hook 62, the helical wire 61 rotates along its helical direction, It comes out in the same direction as the force is applied.

The pull-out connector 64 has a structure capable of twisting in response to the number of times of the helical wire 61 wound or more times. For example, the pullout connection 64 may be a belt of some length and flexible. In particular, the lifting belt is not damaged even if it is twisted along the longitudinal direction of several times. However, the present invention proposes a rotating hook 65 as such a pulling coupling.

The rotation hook 65 includes a hook portion 651 and a locking portion 652. The hook portion and the locking portion are rotatably connected to each other by a rotation connection portion 653. [ The rotation connection portion 653 transmits the force in the drawing direction, but the rotation about the drawing direction is free.

As shown in Fig. 16, when the hook portion 651 is hooked on the hook portion 62 of the helical wire 61 and the hook portion 652 is pulled by pulling a tool or the like, (61) is pulled out in a pulling direction. As the spiral wire rotates, the hook portion 651 rotates together. However, the hook portion 651 rotates together with the hook portion and the rotation connecting portion 653, 652 do not rotate. Therefore, when a person grips the hook 652 and pulls it out or pulls it out by heavy equipment, the helical wire can be pulled out without splashing the person's arm or twisting the heavy equipment. As the helical wire is loosened, the spiral wire section unwound from the wire net is plastically deformed by the pulling force and spreads out almost linearly. Therefore, as shown in Fig. 18, the spirally wound wires are plastically deformed almost linearly, making reuse difficult, but they can be recycled as scrap iron.

When the inner diameter of the helical wire 61 is set to about 20 to 35 mm in consideration of the diameter of each wire of the wire net, the wire of the two wire net is not easily extended while it is easy to insert the helical wire 61. If the inner diameter d of the spiral is less than 20 mm, it is difficult to insert the spiral into two or more overlapping wires. If the inner diameter d of the spiral is larger than 35 mm,

As a result of the experiment, when the tensile strength of the helical wire 61 is about 390 to 780 N / mm ² , when the inner diameter d of the helical wire is set to about 20 to 35 mm as described above, It was confirmed that the helical wire 61 smoothly escaped. If the lead of the helix is smaller than 60 mm, there is a problem that the wire is deformed at the time of drawing, and the inside diameter of the helix is reduced, and the wire of the wire is tightly caught. On the other hand, if the lead of the helix is longer than 105mm, the number of turns of the helix becomes too small and the two wires can not be connected properly.

When the inner diameter d of the spiral is about 20 to 35 mm and the lead 1 of the spiral is 60 to 105 mm and the tensile strength is smaller than 390 N / mm ² , the spiral wire can not withstand the pressure of the contents filled in the barrier wall There is a problem that the wire of the two-wire mesh is tightly caught or broken. Conversely, when the tensile strength is 780 N / mm ² or more, the strength is excessively high, which leads to waste of material and cost.

Drawing power is most convenient to utilize heavy equipment, but it can be done by person if it is difficult to utilize heavy equipment. In this case, the pulling force can be amplified by using the chain block to give sufficient pulling force. That is, the chain block is set up above the unit barrier with the contents in the unit barrier, the hook 62 of the helical wire is connected to the hook of the chain block via the pullout connection 64, It is possible to pull out the helical wire 61 without applying a large force. When this happens, the wire mesh opens and you can easily pour out the contents.

The spiral wire 61 is disposable but the number of turns of the helical wire 61 is much smaller than the number of turns of the spring-like wire 51. Therefore, Unlike FIG. 5, only one helical wire is used, so consumption of wires is extremely small, which can save much more material than the structure of FIG. In addition, it is more economical to use the helical wire 61 in view of the fact that the straight wire 52 is also damaged or lost, and recycling is hardly achieved.

[Application of the coupling member for easy formation]

FIG. 19 is a perspective view showing a state of use of a foldable type fire wall capable of applying the simple connection form coupling member according to the present invention, FIG. 20 is a front view showing a half-folded state of the fire wall of FIG. And FIG. 22 is a top plan view of the barrier of FIG. 19 viewed from above.

19 to 21 show only the portion of the barrier wall constituting one compartment space s, which is actually connected in a continuous manner as shown in Fig. In FIG. 22, the bottom wall of the barrier wall is omitted in order to simplify the illustration.

19 to 22, the folding type barrier walls to which the helical wire 61 of the present invention is applied include a plurality of barrier ribs 920 arranged in line and facing each other, and a plurality of barrier ribs 920 connecting the side walls between the adjacent two barrier ribs And a bottom wall 940 connecting the bottom surface between the adjacent two partition walls.

The side wall 930 includes two divided side walls 931 and 932 and the bottom wall 940 also includes two divided bottom walls 941 and 942.

The first divided sidewall 931 of the two divided sidewalls is connected to the side end of one side wall 920 and the second divided sidewall 932 is connected to the side end of the other side wall 920. And also between the two divided side walls 931 and 932.

Similarly, the first divided bottom wall 941 of the two divided bottom walls is connected to the bottom of the first partition wall 920, and the second divided bottom wall 942 is connected to the bottom of the other partition wall 920. It is also connected between the two split bottom walls 941, 942.

The connecting portion between each of the wall members 920, 931, 932, 941, 942 may be connected to the connecting member 50, which is a spring-shaped wire.

According to this structure, as shown in the figure, the two divided sidewalls 931 and 932 are folded into a space between the two partition walls 920 (see FIGS. 21 and 22), and the two divided bottom walls 941 and 942 are formed between the two partition walls 920 (See Fig. 20), and they can be superimposed on each other.

Therefore, the barrier walls to which the simple connection formulating member 60 according to the present invention can be applied can be stored in a state where they are stacked on each other and can be used as shown in FIG. 19 by pulling out two barrier walls at the site when necessary.

19, after the barrier wall is opened, it is possible to fasten the portions where the side walls and the bottom walls 931 and 941, and 932 and 942 face each other with a ring (not shown) or the like to maintain the shape .

Although the bottom wall 940 is formed in the embodiment of the present invention, it is also possible to omit the bottom wall if necessary.

22, the folding type barrier according to the present invention includes a connecting member 50 (see FIG. 22) provided between a side wall 930 and a partition wall 920 constituting one compartment space s and two adjacent divided side walls 931 and 932, At least one of them is made of the form connection member 60 in a simple manner.

Specifically, the first divided sidewall 931 and the second divided sidewall 932 of the connecting members connecting the wall members constituting the first divided space s1 in the first divided space s1 ) Is easily formed into the form connection member 60a.

Next, in the second partition space s2, a connecting member between any one of the partition members 920 and the second divided side wall 932, which connect the wall members constituting the second partition space s2, In the third partition space s3, any one of the partition members 920 connecting the wall members constituting the third partition space s3 and the first partition wall s2, The connecting member between the first and second partitioning spaces 931 and 931 is easily formed into the form connection member 60b and shared one formability coupling member 60b of the two compartment spaces.

Next, in the fourth partition space s4, the connection between the first divided sidewall 931 and the second divided sidewall 932 of the connecting members connecting the wall members constituting the fourth divided space s4, Members are all formed into the form connection members 60c and 60d.

When the form connection member is formed simply between the divided side walls of a side wall such as the first compartment space, a barrier wall may be provided so that the simple connection member is disposed on the side exposed to the outside in accordance with the installation direction of the barrier wall .

When the two compartment spaces share one simple form coupling member such as the second and third compartment spaces, it is possible to open the two compartment spaces by releasing one simple form coupling member in the demolition process of the barrier wall.

It is advantageous in that when the form coupling member is formed easily on both sides of the barrier wall as in the fourth partition space, the installation direction of the barrier wall is not limited.

Particularly, when the two compartment spaces, such as the second and third compartment spaces, share one simple form coupling member, it is possible to open the two compartment spaces by releasing one simple form coupling member, Shaped wire 51 and the straight wire 52 shown in Fig. 5 are difficult to implement. This is because three wall members (the partition wall 920 between the two compartment spaces and the second partition wall 920 of the second compartment space s2) are provided at positions where one of the simplex forming link members 60b is shared in the second and third partition spaces. Shaped wire 51 and the straight wire 52 are connected at the same time to the first divided side wall 931 of the third division space s3 and the first divided side wall 931 of the third division space s3, And the linear wire 52 must be fastened to the overlapping area. However, it is not so easy to fasten it, and even if it is fastened, after the fastening, the three spring connecting members are entangled with each other, and the flow of the wall member connected thereto is limited, so that the wall members can not be superposed. However, according to the structure of the above embodiment of the present invention, there is no problem that three wall members connected to one easy-to-use coupling member 60b are overlapped with each other.

Therefore, when the partition wall and the divided side walls of the partition spaces of the left and right partition walls are connected to each other by the simple connection type coupling member 60b for each of the two compartment spaces, the barrier wall is easily stacked and unfolded without difficulty, As well as reducing the number of later releases to 1/2.

 On the other hand, the easy-to-connect coupling member 60 is applicable not only to the side wall 930 but also to the bottom wall 940. That is, if the connection part between the bottom wall 940 and the partition wall 920 and / or the connection part between the two divided bottom walls 941 and 942 is formed of the form connection member 960, it is easy to remove the form connection member It is easy to open the bottom wall.

The above-mentioned geosynthetic fibers may be inserted into the compartment space (s) of the barrier wall to prevent the leakage of the gypsum, and a polyurethane film may be applied to the geosynthetic fiber by compression coating to prevent the geosynthesis of the geosynthetics.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the invention is not limited to the disclosed exemplary embodiments. It is obvious that a transformation can be made. Also, the use of the present invention is not limited to the range described in the present specification, and can be used in various aspects and applications. Although the embodiments of the present invention have been described in detail above, the effects of the present invention are not explicitly described and described, but it is needless to say that the effects that can be predicted by the configurations should also be recognized.

10: Side wire mesh
20: Connecting wire mesh
30: Bottom wire mesh
40: support wire net (supporting member)
50:
51: spring-shaped wire
52: Straight wire
60, 60a, 60b, 60c, 60d:
61: Draw-out type spiral wire
62:
64: Pullout connector
65: Rotating hook
651:
652:
653:
70: Geo fiber
71: inner side contact of the side wall
72: Inner contact portion
73: Inner contact portion of bottom wire mesh
74: Support wire inner contact
78: Safety indication
79: outer overlapping portion
80: Contents (soil, plant)
920:
930:
931, 932:
940: bottom wall
941, 942: split bottom wall
d: inner diameter of the spiral
l: lead of the spiral (pitch)

Claims (20)

A pair of side wire netting (10) facing each other and spaced apart from each other;
A pair of joint surface wire meshes (20) connecting the opposing ends of the pair of side surface mesh wires to each other to define a joint surface of a space defined by the pair of side surface mesh wires;
A bottom wall connected to a lower end of the pair of side wall wires or connected to a lower end of the pair of side wall walls to define a bottom surface of the space defined by the pair of side wall wires and the pair of splice- A cotton wire net 30;
20 and 30 are pivotally connected to each other at a connection portion of the wire meshes 10, 20 and 30, ; And
A pair of side wall wire net, a pair of side wall wire net, and a bottom side wire net, in order to contain the contents 80 in a space defined by the pair of side wire net, And a geosynthetic fiber (70) covering the inner surface of the unit barrier wall
One of the connecting members fitted to the ends of the two wire meshes to be connected is connected to the spiral wire 61 for drawing release,
The spiral wire 61 for drawing release has an inner diameter d of 20 to 35 mm and a lead 1 of 60 to 105 mm in the spiral and the wire has a tensile strength of 390 to 780 N / mm ² , A wire which keeps the spiral shape of the spring even when it is not applied,
A pull-out connection 64, which is free to twist, is connected between one end of the helical wire and the feed of the pull-out force in correspondence with the number of times or more times the helical wire 61 is unwound, Wherein the wire netting to be connected and the spirally wound wire portion to be connected are rotated and come out along the shape of the spiral wire as the spiral wire is pulled in the longitudinal direction while the spiral wire is rotatably supported by the unit barrier .
The method according to claim 1,
Wherein a connecting member is further inserted in a vertical direction in an intermediate portion of the joint network 20.
The method according to claim 1,
In order to prevent the pair of side wire nettings 10 from bulging out due to the contents, the middle side portions of the pair of side wire nettings 10, which are disposed between the pair of side wire nettings 10, And a supporting member connected to the unit barrier.
delete delete delete The method according to claim 1,
Characterized in that the spiral wire (61) for drawing-out is formed with a ring portion (62) at at least one end thereof.
The method according to claim 1,
Wherein the geosynthetic fiber is formed by compressing and coating a polyurethane film to prevent peeling of the geosynthetic fiber.
A connecting member which is connected to the connecting wall 20 of the unit barrier walls according to any one of claims 1 to 3, and which is fitted in the connecting wall 20 is a spring-shaped wire 51, Wherein the two spring-shaped wires (51) are overlapped with each other, and a linear wire (52) is inserted into the spring-shaped wires (51) along the longitudinal direction thereof to connect two or more unitary walls.
A barrier wall comprising at least a plurality of barrier ribs (920) disposed at least facing each other and side walls (930) connecting side faces between the facing barrier ribs (920)
The side wall 930 includes two or more divided side walls 931 and 932,
A space surrounded by the side wall 930 connecting the facing partition wall 920 and the side face of the partition wall 920 becomes the partition space s,
The shape of the partition space s is adjusted by overlapping or separating the partition walls 920 facing each other,
A connecting member is provided between the connecting portion of the side wall 930 and the partition wall 920 and the adjacent two divided side walls 931 and 932,
At least one of the connecting members 50 provided between the side wall 930 and the partition wall 920 constituting one compartment space s and between the two adjacent divided side walls 931 and 932 can be easily connected to the form connecting member 60 Lt; / RTI >
The simple connection form coupling member 60 includes a spiral wire 61 for drawing out,
The spiral wire 61 for drawing release has an inner diameter d of 20 to 35 mm and a lead 1 of 60 to 105 mm in the spiral and the wire has a tensile strength of 390 to 780 N / mm ² , A wire which keeps the spiral shape of the spring even when it is not applied,
A pull-out connection 64, which is free to twist, is connected between one end of the helical wire and the feed of the pull-out force in correspondence with the number of times or more times the helical wire 61 is unwound, Wherein the wire netting and the spirally wound wire portions to be connected are rotated and released along the shape of the spiral wire as the spiral wire is pulled in the longitudinal direction while the spiral wire is rotatably supported by the rotary shaft.
A barrier wall comprising at least a plurality of barrier ribs (920) disposed at least facing each other and side walls (930) connecting side faces between the facing barrier ribs (920)
The side wall 930 includes two or more divided side walls 931 and 932,
A space surrounded by the side wall 930 connecting the facing partition wall 920 and the side face of the partition wall 920 becomes the partition space s,
The shape of the partition space s is adjusted by overlapping or separating the partition walls 920 facing each other,
A bottom wall 940 including two or more divided bottom walls 941 and 942 is connected to the lower end of the facing partition wall 920,
A connecting member is provided between the connecting portion of the side wall 930 and the partition wall 920, the adjacent two divided side walls 931 and 932, the connecting portion between the bottom wall 940 and the partition wall 920 and the adjacent two divided bottom walls 941 and 942 And,
Between the side wall 930 and the partition wall 920 constituting one compartment space s, between the bottom wall 940 and the partition wall 920, between the two adjacent divided side walls 931 and 932 and between the adjacent two partition bottom walls 941 and 942 At least one of the coupling members is formed of a coupling member (60)
The simple connection form coupling member 60 includes a spiral wire 61 for drawing out,
The spiral wire 61 for drawing release has an inner diameter d of 20 to 35 mm and a lead 1 of 60 to 105 mm in the spiral and the wire has a tensile strength of 390 to 780 N / mm ² , A wire which keeps the spiral shape of the spring even when it is not applied,
A pull-out connection 64, which is free to twist, is connected between one end of the helical wire and the feed of the pull-out force in correspondence with the number of times or more times the helical wire 61 is unwound, Wherein the wire netting and the spirally wound wire portions to be connected are rotated and released along the shape of the spiral wire as the spiral wire is pulled in the longitudinal direction while the spiral wire is rotatably supported by the rotary shaft.
delete The method according to claim 10 or 11,
The simple connection form coupling member 60b includes one partition wall 920 for partitioning the two partition spaces s2 and s3 and two divided partition walls 932 and 931 facing one end of the partition wall 920 The two compartments S2 and S3 are opened together when the form coupling member 60b is released easily.
The method according to claim 10 or 11,
The geomorphic fiber is inserted in the compartment space (s)
Wherein said geosynthetic fiber is formed by compressing and coating a polyurethane film to prevent peeling of geosynthetic fibers.
A spiral wire (61) for unscrewing which can be wound around the ends of two wire meshes or walls to be connected at a connection portion of the wire mesh (10, 20, 30) constituting the unit barrier or the walls (920, 930, 931, 932, 940,
The spiral wire 61 for drawing release has an inner diameter d of 20 to 35 mm and a lead 1 of 60 to 105 mm in the spiral and the wire has a tensile strength of 390 to 780 N / mm ² , A wire which maintains the spiral shape of the spring even when it is not applied,
A pull-out connection 64, which is free to twist, is connected between one end of the helical wire and the feed of the pull-out force in correspondence with the number of times or more times the helical wire 61 is unwound, Characterized in that the wire netting to be connected and the spirally wound wire portion to be connected are rotated and released along the shape of the spirals as the spirally wound wire is pulled in the longitudinal direction with the spirally wound wire being rotatably supported on the rotating shaft, Spiral wire for.
delete 16. The method of claim 15,
Characterized in that the spiral wire (61) for drawing-out is formed with a hook (62) at least at one end thereof.
A spiral wire for drawing-out according to any one of claims 15 to 17,
And a pull-out connecting member (64) provided between one end of the helical wire and the feed of the pulling force, wherein the pull-out connecting member (64) is free to twist in accordance with the number of times or more times the helical wire (61) is unwound.
19. The method of claim 18,
The pull-out connector 64 is provided with a through-
A hook portion 651 connected to the hook portion 62;
A hook portion 652 located at the opposite portion of the hook portion; And
(65) including a hook portion (651) and a rotation connecting portion (653) for connecting the hook portion (652) to the pulling shaft in a rotatable manner.
A method of separating a spiral wire (61) for pull-out on a connection of a wire mesh (10, 20, 30) or walls of a firewall (920, 930, 931, 932, 940, 941, 942)
Connecting one side of the draw-off port (64) to one end of the helical wire and connecting the other side of the draw-off port to the supply of the pull-out force;
Pulling out the supply portion of the pulling force in a direction in which the helical wire is to be pulled out; And
And a step of releasing the pull-out spiral wire (61) by rotation of the draw-off connector as the pull-out portion of the pull-out force is pulled out and coming out from the connection portion between the wire- Wire separation method.

Images