JP3668964B2 - Protective fence - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a protective fence such as a rock fall protection fence that attenuates and stops fallen energy held by falling objects such as falling rocks and avalanches, an avalanche protection fence, and an avalanche prevention fence that prevents the occurrence of avalanches.
[0002]
[Prior art]
In order to protect roads and private houses from falling objects such as falling rocks and avalanches, falling rock protection fences and avalanche protection fences are installed on the slopes, and avalanche prevention fences are installed to prevent the occurrence of avalanches.
As these protective fences, a fence in which a protective net c is stretched between pillars b erected on a slope a with a predetermined interval is known (see FIG. 8). In order to prevent the inclination of the support column b toward the slope a valley side, the slope a mountain side and the upper part of the support column b are connected by a rope d1 or the like, and in order to prevent the inclination of the support column b toward the mountain side, Are connected by a rope d2 or the like. Furthermore, the ropes d3 and the like are connected between the upper portions of the struts b at both ends and the side ground in the protective fence surface.
According to this protection fence, the impact energy possessed by the falling rocks is absorbed and stopped by the strength of the protection net c and the strut b. Moreover, the occurrence of an avalanche is prevented by installing a plurality of rows on the slope a.
[0003]
[Problems to be solved by the invention]
However, the conventional protective fence has the following problems.
<A> Since the protective net is suspended by a plurality of horizontal ropes installed on both ends of the support pillar, energy is absorbed only by the span between the striking struts when a falling rock collides, so the amount of deformation is large. It is easy to be damaged and broken.
<B> The slope on which the protective fence is installed is rarely flat and usually has undulations. In such a site, it is technically difficult to install a single long net corresponding to the undulation of the slope. In addition, when there is a difference in height between the columns, it is necessary to stretch the protective net in a parallelogram, but if it is stretched forcibly, wrinkles will occur and there will be a problem of reduced performance and deterioration of landscape.
<C> If rock fall, avalanche, or snow pressure acts diagonally against the net surface, and the side retaining rope of the end strut of the protective fence is subjected to excessive deformation or cutting, the space between the struts will be rectangular Therefore, it becomes difficult to suppress deformation in the surface of the protective fence, and the entire protective fence is easily destroyed.
<D> Since both ends of the protective net are held, when a falling rock collides, the upper and lower edges of the net are bent so as to approach the center of the net, and the vertical width of the protective net to be the receiving surface is reduced. Therefore, when the next falling rock falls, it passes through the upper side or the lower side of the protective net and does not serve as a protective fence.
<E> Since a single protective net is stretched over a wide range, if the protective net is damaged, the set of nets including those that are not damaged will be replaced, which is uneconomical.
<F> In order to eliminate the above-mentioned problem, it is possible to divide and stretch the protective net. However, the collision object is allowed to pass through the gap between the adjacent protective nets, so that it does not serve as a protective fence.
[0004]
OBJECT OF THE INVENTION
The protective fence of the present invention was made to solve the above-mentioned problems, and with respect to impact force and load acting locally, the protective fence that stretches around absorbs energy and resists the load. The purpose is to provide a fence.
Another object of the present invention is to provide a protective fence in which a net can be easily installed without reducing performance in response to undulations on a slope.
It is another object of the present invention to provide a protective fence that has a large resistance to deformation in the surface of the protective fence even when rockfalls, avalanches, and snow pressure act obliquely with respect to the net surface.
It is another object of the present invention to provide a protective fence with a small reduction in height even when a falling rock or avalanche collides with the protective net.
It is another object of the present invention to provide a protective fence that only needs to be replaced when the protective net is damaged.
A further object of the present invention is to provide a protective fence in which falling rocks do not pass through the gaps between the protective nets.
The present invention is intended to achieve at least one of the above objects.
[0005]
[Means for Solving the Problems]
In order to achieve the above-mentioned object, the guard fence of the present invention is a guard fence in which a guard net is stretched between struts erected at a predetermined interval, and has a triangular net of an upright triangle and an inverted triangle. Triangular nets are continuously combined, and the above-mentioned erecting triangular triangular nets and inverted triangular triangular nets form a rhombus mesh by stretching the rope diagonally, and between the adjacent opposite sides of the triangular nets. It is characterized in that Configure the strip-shaped guard net linked via a connecting member so that the variance transmission that can force. In addition, the protective fence of the present invention is characterized in that it is connected via a buffer in the middle of the connector. In addition, the triangular net of the guard fence of the present invention is characterized in that a plurality of rope intersections are fixed to each other to form a rhombus mesh. Further, the triangular net of the protection fence of the present invention is formed by forming a rhombus mesh by attaching a shock absorber to the intersection of a plurality of ropes, and when the force exceeding the set gripping force acts on the intersection of the ropes, It is characterized in that the ropes are allowed to slide relative to each other. The protective fence according to the present invention is characterized in that a protective net is stretched between the upper part of the support column and the slope mountain side so that the slope valley side is convex. The protective fence according to the present invention is characterized in that a protective net is stretched between the upper portion of the support column and the slope valley side so that the slope mountain side is convex. The protective fence according to the present invention is characterized in that the lower part of the support and the slope mountain side and the slope valley side are respectively connected by lower retainer ropes.
[0006]
DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
[0007]
<A> Protective fence FIG. 1 shows an example of the protective fence 1.
The protective fence 1 is composed of a support column 4 standing on a slope 10 at a predetermined interval, and a protection net 2 stretched around the support column 4 in a belt shape.
A strip-shaped protective net 2 is formed by continuously combining a large number of substantially triangular capturing nets (hereinafter referred to as triangular nets) 3.
The adjacent opposite sides of the triangular nets 3 are connected via a connector 6.
[0008]
<B> Protective net The protective net 2 includes an erecting triangular triangular net 3A (triangular net 3 with the apex upward and the bottom horizontal when viewed from the front) and an inverted triangular triangular net 3B (viewed from the front). Then, the triangular net 3) with the apex at the bottom and the base at the horizontal is continuously combined alternately to form a strip shape (see FIGS. 1 and 3).
The triangular nets 3 are sequentially arranged with respect to the pillars 4 so that the apexes and the bases thereof are alternately positioned, and the erecting triangular triangular nets 3A and the inverted triangular triangular nets 3B are continuously combined alternately. it can.
Opposite sides of adjacent triangular nets 3 are connected by a plurality of connectors 6.
In this way, the band-shaped protection net 2 is formed by combining the triangular nets 3.
[0009]
<C> Triangular net Triangular net 3 is a net formed by crossing ropes (wire ropes), PC steel wires, PC steel strands, wires such as carbon fibers, etc., and the overall shape is substantially equilateral triangle or substantially two. Form an equilateral triangle.
A frame is formed around the triangular net 3 with a frame rope 32, and a rope 33 is diagonally stretched left and right to form a rhombus mesh. The frame rope 32 is formed thicker than the rope 33.
The rhombus intersection 34, that is, the intersection 34 of the left and right ropes 33, 33 is fixed with a fastening jig or the like, or the ropes 33 are knitted together to restrain the movement of the ropes 33 from each other.
Attach the attachment rope 31 to each vertex of the triangle. The attachment rope 31 is used to stretch the triangular net 3 in a triangular shape.
When stretching the upright triangular net 3A, one of the three attachment ropes 31 is connected to the protrusion 41 on the upper side of the column 4 and the other two are fixed points (anchors etc.) on the ground of the slope 10 7 to connect respectively. Further, when the inverted triangular triangular net 3B is stretched, one attachment rope is connected to a fixed point (anchor or the like) 7 on the ground of the slope 10, and two are connected to the protrusion 41 on the upper side of the support column 4, respectively.
The attachment rope 31 may be provided with an adjustable connector such as a turn buckle so that the slack and tension of the triangular net 3 can be adjusted.
Further, without attaching the attachment rope 31 to each vertex of the triangular net 3, each vertex of the triangular net 3 may be directly connected to the upper part of the support 4 or the fixed point 7 on the ground, and connected via a shock absorber. Also good.
[0010]
<D> The support column 4 is made of various known rigid materials such as steel and concrete columns.
The lower part of the support column 4 is installed on a foundation concrete (precast concrete plate) 42. Or the lower part of the support | pillar 4 is directly rotatably installed on a slope ground.
A lower stay rope 45 is attached to the lower part of the support column 4, and the other end of the lower stay rope 45 is connected to the anchors 7 and 7 on the mountain side of the slope 10 and the anchor 8 on the valley side of the slope 10 along the slope 10.
The lower support rope 45 is stretched in a Y shape around the support column 4 so that the lower portion of the support column 4 is stabilized.
The lower retainer rope 45 may be attached to the foundation concrete 42 (see FIG. 6).
[0011]
On the other hand, in order to perform the original function of the support column, it is necessary to prevent the support column 4 from tilting toward the mountain side or the valley side of the slope 10.
Conventionally, in order to prevent the slope 4 of the support column 4 from tilting toward the valley, the mountain side of the support surface 10 and the upper part of the support column 4 are connected with a reed rope or the like.
In the present invention, as described above, the upper end portion of the triangular net 3 is connected to the upper portion of the support column 4 and the lower end portion of the triangular net 3 is connected to the fixing point (anchor) 7 of the inclined surface 10. Tilt to the 10th valley side is prevented, and it is possible to omit the reed rope and the like.
Further, in order to prevent tilting of the slope 10 to the mountain side of the slope 10 due to strong wind or impact reaction toward the mountain side of the slope 10, the holding rope 5 is connected to the protrusion 41 of the pillar 4 on the valley side of the slope 10. The other end is connected to a fixed point (anchor or the like) 8 of the slope 10. When connecting the stay rope 5 to the anchor 8, a buffer 9 described later may be interposed.
[0012]
The strength of the support column 4 is such that the plastic deformation does not exceed the limit value when the impact of the falling rock 11 or the like is indirectly received through the protective net 2 or when the impact is directly applied to the support column 4. Set it.
In addition, the support column 4 may be positively tilted through the hinge 43 or the like (see FIG. 2). In this case, the stay rope 5 slides against the shock absorber 9 to absorb the shock. Therefore, the column 4 does not need great rigidity.
In addition, by installing the support column 4 in this way, there is an advantage that no bending moment is generated in the support column 4 and only the axial compression force acts and an economical cross section can be obtained.
Further, there is an advantage that even if the support column 4 is damaged, the support column 4 can be removed at the hinge 43 and replaced easily.
[0013]
<D> Connector connector 6 is, for example, a connecting rope (wire rope) or the like configured by connecting together a plurality of (3 bundles) strand bundles. When a connection rope is used, it is hooked on the frame rope 32 of the triangular net 3 and fixed with a wire clip.
By connecting adjacent opposing sides of the triangular net 3 with the connecting tool 6, the interval between the triangular nets 3 is prevented from expanding beyond a certain level.
Further, when the falling rock 11 or the like collides with one triangular net 3 by connecting with the connecting tool 6, the impact energy is sequentially transmitted to the adjacent triangular net 3 through the connecting tool 6, and as a result, the impact energy is dispersed. Will be absorbed.
In addition, as long as the connection tool 6 connects the adjacent opposing sides of the triangular net 3, various connection means may be used.
[0014]
<E> As an example of the buffer rope shock absorber 9 for the reed rope, there may be mentioned one constituted by a U-bolt 95, two clamping bodies 91, a fastening bolt 92 and the like as shown in FIG.
The holding body 91 is engraved with a groove for housing the stay rope 5, and the stay rope 5 is housed therein and the bolt 92 is tightened to grip the stay rope 5. The gripping force (friction force) of the holding rope 5 can be adjusted by the fastening force of the bolt 92.
The holding rope 5 is gripped with a predetermined friction force, and when the tension higher than the setting acts on the holding rope 5, the extra length portion 51 is allowed to slide.
The shock absorber 9 is attached to the anchor 8 by bolting with a U bolt 95.
Further, the frictional force for gripping the holding rope 5 is strong enough to cause the extra length portion 51 to start sliding from the holding body 91 before the plastic deformation of the support column 4 reaches the limit value when an impact is applied to the protective net 2. Set it to the same size.
The shock absorber 9 may use other members such as a wire clip as long as it can fasten the holding rope 5 with a predetermined gripping force.
[0015]
[Action]
Hereinafter, the operation of the protective fence of the present invention will be described.
[0016]
<I> Installation of the protective fence The triangular net 3 is connected to the upper part of the support column 4 and the fixed point (anchor 7) on the slope 10 mountain side, and the erecting triangular triangular net 3A and the inverted triangular triangular net 3B are continuous. The protective net 2 is installed so as to be convex on the valley side.
The holding rope 5 is connected to the upper part of the support column 4 and the anchor 8 of the slope 10.
The protective fence 1 is installed without tilting to the mountain side or the valley side of the slope 10 by the protective net 2 and the holding rope 5 connected to the support column 4.
[0017]
<B> Impact-absorbing action when falling rocks When the falling rocks 11 etc. collide with the triangular net 3, the triangular net 3 is deformed and received so as to wrap the falling rocks 11 etc.
In the present invention, the rhombus 33 is obliquely stretched from side to side on the inside of the triangular net 3 to form a rhombus mesh, so that when the impact from the falling rock 11 or the like is received, the rhombus spreads and deforms into a square, so that it is greatly bent Deformation will attenuate the impact energy.
In this case, since all the rhombuses in the range where the rock fall 11 collides spread and deform into a square and can be greatly bent and deformed, even if there is a large scale rock fall, the impact energy can be sufficiently attenuated.
Further, the impact acting on the triangular net 3 finally acts on the support column 4 from the attachment rope 31 at each vertex of the triangular net 3.
The impact force (impact energy) acting on the column 4 is a direction in which the column 4 is tilted toward the mountain side of the slope 10.
Since the holding rope 5 is connected to the support 4, a tensile force acts on the holding rope 5 when the support 4 is inclined to the mountain side. When the shock absorber 9 is provided on the anchor end side of the stay rope 5, the stay rope 5 starts to slide when the tensile force exceeds the gripping force of the shock absorber 9. This sliding resistance attenuates impact energy.
[0018]
Further, when the falling rock 11 or the like collides with the triangular net 3, the triangular net 3 is deformed, so that the interval between the opposing sides of the triangular net 3 and the triangular net 3 is increased.
If the protective net 2 is simply divided as in the prior art, the divided portion is opened along with the deformation, and the falling rock 11 or the like easily passes.
In the present invention, since the opposing sides of the adjacent triangular nets 3 are connected by the connector 6, the interval between the triangular nets 3 and the triangular nets 3 does not spread beyond a certain level, and a collision object passes through. There is nothing.
In addition, when the falling rock 11 or the like collides with one triangular net 3, the impact energy is sequentially transmitted to the adjacent triangular net 3 through the connector 6, and the impact energy is dispersed when transmitted. Will be absorbed. That is, the force is transmitted to the impact force or load acting locally and the energy is distributed through the connector 6 to dissipate the energy, and the entire guard fence 1 stretched can absorb the energy.
[0019]
When the falling net impact force or snow pressure acts by projecting the triangular net 3 convexly on the valley side of the slope 10, the triangular net 3 protrudes further on the valley side of the slope 10 and above the triangular net 3, In the axial direction of 4, the triangular net 3 is deformed in the slope direction below the triangular net 3.
As a result, the axial force on the support column 4 increases, and the anchor anchor force on the valley side of the slope 10 decreases.
In addition, the reaction force toward the valley side of the slope 10 increases below the triangular net 3, and the shearing force is dominant over the pulling force of the anchor 7. If the anchor 7 is reinforced against the shearing force, a small pull-out resistance is sufficient.
[0020]
When the triangular net 3 is greatly damaged by a large falling rock 11 or the like, the attachment rope 31 can be removed from the protrusion 41 and the anchor 7 and the damaged triangular net 3 can be easily replaced.
[0021]
Second Embodiment of the Invention
Next, another embodiment according to the present invention will be described.
[0022]
In the first embodiment, the triangular nets 3 are merely connected to each other by the connecting tool 6, but a buffer tool 60 may be interposed in the middle of the connecting tool 6.
As an example of the shock absorber 60, one constituted by two clamping bodies 61, a bolt 62 for tightening, a nut 63, and the like (see FIGS. 3 and 4) can be mentioned.
The holding body 61 is engraved with two grooves 64 each for accommodating a connecting rope as the connecting tool 6 of the adjacent triangular net 3, and the holding body 61 is connected so that the connecting rope is accommodated in the groove 64. The rope 6 abuts from both sides, the bolt 62 is passed through the through-hole 65 and the nut 63 is tightened, and the connection rope 6 is held. The gripping force (crimping force) of the connecting rope 6 can be adjusted by the fastening force of the bolt 62 and the nut 63.
The connecting ropes 6 of the triangular net 3 adjacent to the two grooves 64 and 64 are accommodated, respectively, and an extra length portion 6a that allows the connecting rope 6 to slide sufficiently is protruded (see FIG. 3).
The connection rope 6 is gripped with a predetermined frictional force by the bolt 62 and the nut 63, and when the tension more than the setting acts on the connection rope 6, the extra length portion 6a is allowed to slide.
Since the connection rope 6 slides with respect to the shock absorber 60 by interposing the shock absorber 60, the impact energy is effectively absorbed.
[0023]
Embodiment 3 of the Invention
In the first embodiment, the crossing portion 34 of the rope 33 is fixed and the mutual movement of the rope 33 is restricted. However, the crossing portion 34 is crossed, for example, so that the ropes 33 can slide relative to each other. A function of absorbing shock energy by attaching the buffer metal fitting 35 can be added (see FIG. 1).
The cross shock-absorbing metal fitting 35 includes, for example, two plate pieces 36 and 36 provided with grooves 37 and 37 in a direction in which the rope 33 intersects, a bolt 38 and a nut 39 and the like for fastening the two plate pieces 36. The ropes 33 are respectively accommodated in the grooves 37, and the ropes 33 are gripped with a predetermined frictional force by bolts 38 and nuts 39. When the frictional force is exceeded, the ropes 33 are allowed to slide relative to each other.
When the falling rock 11 collides, the rope 33 slides on the cross buffer metal fitting 36, and the impact energy can be absorbed more effectively.
[0024]
Embodiment 4 of the Invention
It is necessary to install the protective fence 1 according to the undulation of the slope 10. When the triangular net 3 is formed into an equilateral triangle or an isosceles triangle, and the triangular net 3A of the upright triangle and the triangular net 3B of the inverted triangle are combined, the triangular nets 3 of the same kind are combined continuously or alternately. A protective net 2 suitable for 10 undulations can be obtained.
FIG. 5A shows an example of combining isosceles triangular triangular nets 3, and FIG. 5B shows an example of combining isosceles triangular triangular nets 3 and equilateral triangular triangular nets 3.
Further, the protective fence 1 does not need to be configured by a single plane, and the position of the column 4 can be shifted up and down in consideration of the position of the tree and the undulation of the slope 10.
[0025]
Embodiment 5 of the Invention
In the embodiment so far, the protective net 2 is arranged on the mountain side of the slope 10 and the holding rope 5 is provided on the valley side. On the contrary, the protective net 2 is arranged on the valley side of the slope 10, It is also conceivable to provide a holding rope 5 on the mountain side (FIG. 7).
Since the protective net 2 is the same as that of the first embodiment except that the protective net 2 is arranged on the valley side of the slope 10, the description thereof is omitted.
[0026]
<I> Installation of the protective fence The triangular net 3 is connected to the upper part of the support column 4 and the fixed point (anchor 7) on the slope 10 valley side, and the continuous triangular triangle net 3A and the inverted triangular triangular net 3B are continuous. The protective net 2 is installed so as to be convex on the mountain side.
The holding rope 5 is connected to the upper part of the support column 4 and the anchor 8 of the slope 10.
The protective fence 1 is installed without tilting to the mountain side or the valley side of the slope 10 by the protective net 2 and the holding rope 5 connected to the support column 4.
[0027]
<B> Impact force absorbing action when falling rocks The main feature is that the protective net 2 is arranged on the valley side so as to protrude toward the slope 10 mountain side, and has the following impact absorbing action.
(1) When the falling rock 11 collides with the protective net 2, the angle Θ (see FIG. 7A) that the falling rock 11 forms with the net surface of the protective net 2 is the case when the falling rock 11 collides with the protective net 2 arranged on the mountain side. The angle is smaller than the angle Θ1 (see FIG. 7C).
When the falling rock 11 forms an angle with the net surface of the protective net 2, the largest impact force is generated on the protective net 2, and the impact force decreases as the angle decreases.
Since the falling rock 11 collides with the protective net 2 at an angle, that is, with a small angle Θ, the protective net 2 does not generate a large impact force. Or is guided to the ground of the slope 10, collides with the ground, attenuates energy, and stops at the connection portion between the protective net 2 and the slope 10 (see FIG. 7B). Or you may make it pass through the clearance gap between the protection net | network 2 and the slope 10, and stop on the trough side.
Therefore, the axial force acting on the support column 4 and the pulling force acting on the crest rope 5 on the mountain side of the slope 10 are also reduced, and the pulling resistance force of the anchor 8 may be reduced.
(2) Since the angle α (see FIG. 7A) between the protective net 2 and the slope 10 is small, even if an avalanche occurs, the snow pressure per unit area is reduced, and the axial force acting on the column 4 and The tensile force acting on the stay rope 5 on the slope mountain side is also reduced, and the pulling-out resistance force of the anchor 8 may be small.
(3) Even if it is installed on the roadside, the overhang is small, and the protective net 2 does not violate the road construction limit due to falling rocks 11 or snow pressure.
[0028]
【The invention's effect】
Since the protective fence of the present invention is as described above, the following effects can be obtained.
<A> Triangular nets are combined and the opposite sides of adjacent triangular nets are connected by connecting tools, so force is transmitted via connecting tools to impact forces and loads that act locally, such as falling rocks. Energy can be distributed and absorbed by the entire guard fence.
<B> Even if there are undulations on the slope where the protection fence is installed or there is a difference in height between the columns, a protective net is formed by combining triangular nets. Can be stretched. Even in that case, the receiving performance does not decrease.
<C> Since the inside of the triangular net is stretched diagonally to the left and right to form a rhombus mesh, the diamond shape spreads and deforms into a square when impacted by falling rocks, etc. Energy will be attenuated. Moreover, since all the rhombuses in the range subjected to the impact can be expanded and deformed into a square and greatly deformed, the impact energy can be sufficiently attenuated even if there is a large-scale falling rock.
<D> Since a protective net is formed by combining triangular nets that are formed into approximately triangular shapes, if the triangular net is damaged, only the damaged triangular net can be replaced. It is economical and easy to maintain.
<E> Since the opposing sides of the adjacent triangular nets are connected by a connector, the distance between the triangular nets and the triangular nets does not increase beyond a certain level, and collision objects do not pass through.
<F> When a connecting rope is used for the connecting tool and a shock absorber is provided in the middle of the connecting rope, the connecting rope slides between the shock absorber and the impact force can be absorbed more effectively.
<G> Since the upper end of the triangular net is connected to the upper part of the column and the lower end of the triangular net is connected to the ground surface, the column is prevented from tilting to the sloped valley side, and the reserve rope is omitted. Can do.
<H> When the protective net is installed on the valley side so as to be convex on the slope mountain side, the angle formed by the direction of falling rocks and the protective net surface is small, so a large impact force will not be generated. . Therefore, the falling rock after the collision is guided to the protective net or the slope, attenuates the energy, and stops on the slope. In addition, the axial force acting on the struts and the pulling force acting on the hill-side retaining rope can be reduced, and the anchor pull-out resistance force can be reduced.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a protective fence of the present invention.
FIG. 2 is a side view of the protective fence of the present invention.
FIG. 3 is a plan view of the protective fence of the present invention.
FIG. 4 is an explanatory view showing a shock absorber.
FIG. 5A is an explanatory diagram of a guard fence combining a triangular net of isosceles triangles. (B) is explanatory drawing of the guard fence which combined the triangle net of an isosceles triangle and an equilateral triangle.
FIG. 6 is an explanatory view showing a mounting state of the lower part of the column.
FIG. 7A is a side view of the protective fence of the present invention in which a protective net is stretched on the slope valley side. (B) is explanatory drawing which shows the state which the falling rock stopped. (C) is explanatory drawing which shows the case where a falling rock collides with the protection net stretched on the slope mountain side.
FIG. 8 is an explanatory view showing a conventional protective fence.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Guard fence 2 ... Protective net 3 ... Triangular net 4 ... Post 5 ... Retaining rope 6 ... Connecting tool (connection rope)
60..Buffer 7 ... Anchor 8 ... Anchor 9 ... Buffer 10 .... Slope

Claims (7)

A protective fence in which a protective net is stretched between struts erected at a predetermined interval,
Combining upright triangle triangle net and inverted triangle triangle net in succession,
The above-described upright triangle triangle net and inverted triangle triangle net form a rhombus mesh by stretching the rope diagonally,
Characterized in that the between the opposing sides adjacent to each other triangular net, linked via a connecting member so that the variance transmission that can force have configured a strip of protective nets,
Guard fence. The protective fence according to claim 1, wherein a buffer is interposed in the middle of the coupling tool,
Guard fence. In safety barrier according to claim 1 or claim 2, triangular net characterized by being formed into a mesh diamond was fixed to each other intersections of a plurality of ropes,
Guard fence. The protective fence according to claim 1 or 2, wherein the triangular net is formed in a rhombus mesh by attaching a shock absorber to an intersection of a plurality of ropes, and a force exceeding a set gripping force is applied to the intersection of the ropes. When acted, the ropes allowed to slide relative to each other at the intersection,
Guard fence. In the protective fence according to any one of claims 1 to 4, the protective net is stretched between the upper part of the support column and the slope mountain side so that the slope valley side is convex.
Guard fence. In the protective fence according to any one of claims 1 to 4, wherein the protective net is stretched between the upper part of the support column and the sloped valley side so that the sloped mountain side is convex.
Guard fence. In the protective fence according to any one of claims 1 to 6, characterized in that the lower part of the support and the slope mountain side and the slope valley side are respectively connected by a lower back rope.
Guard fence.

Images