JP4916968B2 - Rock fall protection fence - Google Patents

Description

  The present invention relates to a rock fall protection fence installed on a mountain slope, roadside, railway side, or the like.

  Because of its topographical specificity, Japan is prone to natural disasters that cause great damage to roads, railways, and houses due to falling rocks and landslides. For this reason, various measures have been taken to prevent such damage caused by natural disasters.

  With regard to rockfalls, there are cases where a rigid structure such as a concrete cave or retaining wall is provided, and a soft structure rockfall consisting of a steel net and a plurality of spaced columns that hold the net at a certain height. In some cases, a protective fence is provided to deal with the problem.

  Among soft rock fall protection fences, there is a rock fall protection fence for large-scale rock fall using a net made of a steel ring, and is described in, for example, JP-A-6-173221 (Patent Document 1). There is a rockfall protection fence for medium- and small-scale rockfalls, in which wire ropes are assembled in a rhombus-like shape, and wire nets formed by fastening the crossing points of wire ropes with clamps such as U-clips are stretched between columns. is there.

JP-A-6-173221

  The occurrence frequency of rockfalls is much larger for small-scale rockfalls that produce less than about 100 KJ compared to large-scale rockfalls that generate more energy. Many are installed.

  In the case of such a small and medium-sized rock fall protection guard, conventionally proposed, when a rock fall collides with the net, the stress due to the collision is concentrated locally at and around the rock fall collision point of the net. In order to avoid partial breakage of the net at the location, a wire rope is used as a reinforcing material, or a wire net is used as described in Patent Document 1.

  The wire rope used is selected to be relatively strong and strong so as to cope with partial stress concentration due to falling rocks. However, such wire rope increases the net weight and increases the net price. When the net weight increases, the workability deteriorates and the execution cost increases. Increasing net prices inevitably increases the cost of falling rock guards.

  The present invention has been made in view of the above circumstances. The purpose of the present invention is to provide a rockfall protection fence that can sufficiently function for dealing with small and medium-sized rockfalls, has good workability, and can be manufactured at a relatively low cost. Is to provide.

The invention according to claim 1, which achieves the above object, includes a plurality of struts erected on an inclined ground at intervals, upper and lower support rope holders provided at the upper and lower portions of each strut, Falling rocks having upper and lower support ropes held between the upper and lower support rope holders and spanned between the columns, and a net supported between the upper and lower support ropes and stretched between the columns. In the protective fence,
The upper and lower support ropes are
The upper and lower support rope holders are supported so as to be laterally movable in the extending direction,
It is combined with an anchor installed on the ground at a position on the outer side of the end column at the end of the plurality of columns,
When these support ropes are subjected to a tension of a predetermined size or more, a brake device that allows the support ropes to extend while exerting a constant braking force is a range between the vicinity of the end struts and the anchors. Have
The net above
Formed of wire mesh,
Located on the valley side of the column,
An upper edge and a lower edge are attached to the upper and lower support ropes, respectively, so as to be slidable ,
A vertical support rope is mounted on the end column between the upper part and the lower part thereof,
The metal mesh has a side edge attached to the vertical support rope so as to be slidable in the vertical direction .

  According to the first aspect of the present invention, when the falling rock collides with the wire mesh, the wire mesh is arranged on the valley side of the support column, so that the entire wire mesh bulges toward the valley side with the falling stone collision point as a vertex. The impact energy spreads from the location where the rock falls into the wire mesh to the surrounding area.

  The impact energy that has reached the upper and lower edges of the wire mesh acts so that a part of the upper and lower edges are drawn on the upper and lower support ropes to the upper and lower positions of the rockfall collision point. The edge slides on the upper and lower support ropes in the form of a curtain, so that the wire mesh is elastically deformed so that the entirety of the wire mesh gathers toward the falling rock impact site and works for energy absorption.

  The impact energy is further transmitted from the upper and lower edges of the wire mesh to the upper and lower support ropes, bringing a tensile force to both support ropes. When the tensile force exceeds the braking force in the brake device, the impact energy is absorbed according to the braking force. When the upper support rope and / or the lower support rope are extended due to the operation of the brake device, the upper and lower support ropes are supported by the upper and lower support rope holders so as to be laterally movable in the extending direction. Therefore, it is curved and deformed in the state of being pulled out to the valley side between the pillars on both sides of the rockfall collision location corresponding to the length increase due to stretching, and this curved deformation is elastic deformation toward the rockfall collision location of the entire wire mesh Increase the degree further.

Thus, according to the invention described in claim 1, the impact of the falling rock is not received only at the falling rock collision portion of the wire mesh, and the brake device is not immediately activated to absorb the impact energy, Most of the impact energy is absorbed by the entire elastic deformation of the wire mesh that is brought about one after the other until the braking device finishes operating. In addition to this, since only the wire mesh is used as a net, the falling rock protection fence can be manufactured at a relatively low cost, and the falling rock protection fence can be installed relatively easily. In addition, a vertical support rope is mounted between the upper and lower parts of the end column, and the side edge of the wire mesh can slide up and down on the vertical support rope. Is attached. Therefore, the side edge of the wire mesh is attached to the vertical support rope so as to be slidable in the vertical direction, so that the impact force of falling rocks on the wire mesh also causes deformation of the entire wire mesh at the side edge. In addition, the effect of preventing stress concentration on a part of the wire mesh is further enhanced.

  The invention according to claim 2 is the falling rock guard according to claim 1, wherein the wire mesh is attached to the upper and lower support ropes via a helical spring wound around the upper and lower support ropes. It is characterized by being supported.

  According to the invention described in claim 2, since the helical spring has a spiral configuration, each coil portion of the helical spring is engaged with the upper and lower support ropes while being skewed, and as a result, Curtain-like side-sliding movement on the upper and lower support ropes of the wire mesh when deforming toward a rockfall impact point is facilitated, and these connection points at the upper edge and lower edge of the wire mesh. Since the helical spring is pulled out from the upper and lower support ropes according to the magnitude of the stress generated in the wire mesh, the wire mesh can be deformed in a balanced state.

  According to a third aspect of the present invention, in the rock fall protection fence according to the second aspect, the helical spring is supported in a state where an additional helical spring is entangled in the vicinity of the support column, and the wire mesh The upper and lower edges of the are engaged with the additional helical spring in the vicinity of the column.

  As a general tendency, when a falling rock collides with a wire mesh, a large stress is likely to be generated in the wire mesh portion near the column as compared with other portions. According to the invention described in claim 3, in the vicinity of the column, the helical spring has a double helical spring structure in which an additional helical spring is entangled, and a large stress exerted on the wire mesh portion in the vicinity of the column. Accordingly, the double helical spring also extends greatly from the upper support rope and / or the lower support rope, so that the wire mesh can be greatly elastically deformed in the vicinity of the column, and this elastic deformation can cope with a large stress. it can.

According to a fourth aspect of the present invention, in the rock fall protection fence according to any one of the first to third aspects, the end column is fixed to an anchor installed on the ground at the outer position. The lateral rope is supported so as to be prevented from tilting inward.

According to the invention described in claim 4 , the end rock strut is resisted against a large pulling force in the direction of the rock fall collision point received by the end column due to the tension generated in the upper support rope when the rock fall protection fence receives the impact of the rock fall. The support column can be maintained upright.

  According to the present invention, when the impact of the falling rock is received, most of the impact is received in a well-balanced manner due to the large elastic deformation of the entire wire mesh, thereby avoiding stress concentration at the location where the falling wire collides with the wire mesh and breaking the same location. A rockfall protection fence that can be prevented can be provided at a relatively low cost.

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

[First embodiment]
1 to 7 show a rock fall protection fence according to the first embodiment, FIG. 1 is a perspective view of the rock fall protection fence, FIG. 2 is an enlarged perspective view of a support, and FIG. 3 is an enlarged perspective view of a brake device. 4 is a partially enlarged perspective view showing a connection portion between the upper support rope and the wire mesh in the rock fall protection fence, FIG. 5 is a sectional view taken along line V-V in FIG. 1, and FIG. FIG. 7 is a cross-sectional view taken along line VII-VII in FIG. 6.

  As shown in FIG. 1, the rock fall protection fence 1 according to the first embodiment includes four columns 3 a to 3 d erected on a foundation 2 provided on an inclined ground G at intervals in a direction crossing the slope. The upper support rope holder 4a provided at the upper part of each of the columns, the lower support rope holder 4b provided at the lower part, and the upper side held between the support rope holders 4a and spanned between the columns 3a to 3d. A lower support rope 5b held between the support rope 5a and the lower support rope holder 4b and spanned between the support columns 3a to 3d, and supported between the upper and lower support ropes 5a and 5b and stretched between the support columns 3a to 3d. And a net 6 provided.

  FIG. 2 shows a specific configuration of the columns 3a to 3d. Although FIG. 2 has shown the support | pillar 3a arrange | positioned at the edge part of the rock fall protection fence 1, the fundamental structure is the same also in the case of the other support | pillars 3b-3d. As shown in FIG. 2, the main body of the support | pillar 3a is comprised by H-section steel, and the steel plate 31 is attached to the lower end of this H-section steel by orthogonal to the H-section steel by welding. The steel plate 31 is arranged on the upper surface of the concrete foundation 2 (FIG. 1) installed on the ground G. At that time, the bolts planted in the concrete foundation 2 in the insertion holes formed in the steel plate 31. 32 is inserted. Next, a nut 33 is screwed onto the upper part of the bolt projecting on the steel plate 31, and the steel plate 31 is attached to the concrete foundation 2 by tightening this nut, and the column 3 a is erected on the concrete foundation 2. Is done. Between the steel plate 31 and the column 3a, a reinforcing member 34 for reinforcing the column 3a is attached to the mountain side of the column 3a.

  The said support | pillars 3a-3d have a height of 2-3 m, for example, and are installed by the support | pillar space | interval of 6-10 m.

  As shown in FIG. 2, the upper and lower support rope holders 4a and 4b are configured by shackles attached to the support column 3a. The shackles 4a and 4b are attached to the column 3a by engaging a bolt passed between the bolt receiving portions of the shackle with an insertion hole provided in the column 3a. The shackle mounting position is determined so that the shackle loop portion for inserting the side support rope 5b is positioned on the valley side of the support column 3a.

  The upper support rope 5a is preferably a steel wire rope. The upper support rope 5a is inserted into the loop portion of the upper shackle 4a so as to be laterally movable in the extending direction and is bridged between the columns 3a to 3d. The upper support rope 5a spanned between the columns in this way is joined to the anchor 7 that is placed on the ground G at both ends of the upper support rope 5a on the outer side of the end columns 3a and 3d (FIG. 1). Further, the upper support rope 5a is provided with a certain braking force when the upper support rope 5a receives a tension of a predetermined magnitude or more between the anchor 7 and the end support columns 3a and 3d. The upper brake device 8 that allows the stretching of the upper brake device 8 is provided.

  Similarly, the lower support rope 5b is preferably a steel wire rope, and is inserted into the loop portion of the lower shackle 4b so as to be laterally movable in the extending direction, and is spanned between the columns 3a to 3d. The lower support rope 5b spanned between the struts in this way is also coupled to the anchor 7 at both ends thereof on the outer side of the end struts 3a and 3d, and the anchor 7 and the end struts 3a, And a lower brake device 9 that allows the lower support rope 5b to extend while exerting a certain braking force when the lower support rope 5b receives a tension of a predetermined magnitude or more. Yes.

  FIG. 3 shows a specific example of the brake devices 8 and 9. Since these brake devices 8 and 9 have substantially the same configuration, the upper brake device 8 will be described below, and the lower brake device 9 is denoted by “9” in the same portion as the upper brake device 8. The reference numerals starting with the parenthesis 8 are written in parentheses next to the reference numerals for the upper brake device 8, and detailed description thereof is omitted.

  As shown in the figure, the upper brake device 8 includes a loop pipe 8a and a tightening member 8b. The upper support rope 5a is inserted into the loop pipe 8a (the lower support rope 5b is inserted into the loop pipe 9a). Yes. Both end portions of the loop tube 8a are in contact with each other and overlap in a parallel state, and the central range of the overlapping portion is held by the tightening member 8b. Therefore, these both end portions are in frictional contact with each other at the portion held by the tightening member 8b, and are also in frictional contact with the tightening member 8b.

  The loop tube 8a is preferably a steel tube, but may be made of other metal materials or, in some cases, plastic materials. In addition, the connection between the upper support rope 5a and the loop pipe 8a is performed by cutting the upper support rope 5a at the connection point with the loop pipe 8a instead of inserting the upper support rope 5a through the loop pipe 8a as described above. In this dividing part, one end of the upper support rope 5a may be connected to one end of the loop pipe 8a, and the other end may be connected to the other end of the loop pipe 8a. This connection is made, for example, by welding.

  The upper brake device 8 operates as follows. That is, the net 6 of the rock fall protection fence 1 receives the impact of the fall rock, and this impact is transmitted from the net 6 to the upper support rope 5a to generate tension on the upper support rope. If the frictional force by the part is surpassed, a braking force corresponding to the frictional force is brought about. At this time, the diameter of the loop tube 8a is reduced, but a braking force corresponding to the tension that causes the reduced diameter deformation is also provided. These braking forces absorb some of the rockfall energy. Further, the upper support rope 5a is extended by a length corresponding to the diameter reduction as the loop pipe 8a is reduced in diameter.

  By appropriately selecting the diameter of the loop pipe 8a, the upper limit of the extension amount of the upper support rope 5a can be set to a desired value, and the braking force can be selected by appropriately selecting the material and thickness of the loop pipe 8a. Can be set to a desired size. Moreover, although the case where a loop pipe | tube is 1 turn is shown in FIG. 3, double winding or more turns may be sufficient. Further, as the upper brake device 8, in addition to those using the loop pipe 8a, various types of conventionally known forms can be used.

The net 6 is made of a wire mesh. The wire mesh is made of, for example, a high-strength hard steel wire having a thickness (or diameter φ) of 3 mm to ⁵ mm and a strand tensile strength of about 1700 N / mm ² , and less than 15 cm. It is a rhombus wire mesh having a mesh. The wire mesh made of high-strength hard steel wire has high strength and is relatively lightweight, and is easy to handle during transportation and tensioning operations.

  The wire mesh 6 is stretched around the support pillars 3a to 3d by passing the upper support rope 5a through the mesh 6a at the upper edge of the wire mesh 6 (FIG. 4), and similarly at the lower edge of the mesh at the lower edge (not shown). By alternately inserting the support rope 5b and inserting the upper support rope 5a into the upper support rope holder 4a and the lower support rope 5b into the lower support rope holder 4b alternately between struts and for each strut. Achieved. Since the upper and lower support rope holders 4a and 4b are positioned on the valley sides of the columns 3a to 3d, respectively, the wire mesh 6 is connected to the valley side of the columns 3a to 3d as shown in FIG. In FIG. 1, the rear is stretched on the mountain side and the front is on the valley side.

  Instead of engaging the wire mesh 6 with the upper and lower support ropes 5a and 5b as described above, they may be indirectly connected via a shackle (not shown). That is, the support ropes 5a and 5b are connected to the meshes at the upper and lower edges of the wire mesh using shackles that are slidably attached to the support ropes 5a and 5b.

  In any case, the engagement or connection between the support ropes 5a and 5b and the meshes at the upper and lower edges of the wire mesh is performed so that the wire mesh 6 can freely slide and move like a curtain with respect to the support ropes 5a and 5b. Is called.

  As shown in FIGS. 1 and 2, the side edge of the wire mesh 6 is held by a vertical support rope 10 attached to the end support columns 3a and 3d. As specifically shown in FIG. 2, the vertical support rope 10 is a wire that is looped between an upper shackle 11a and a lower shackle 11b that are respectively attached to the upper end and the lower end of the end column 3a (3d). It is formed by a rope. As shown in FIG. 1, the side edge of the metal mesh 6 is engaged with the vertical support rope 10 by inserting the vertical support rope 10 into the mesh of the side edge. The side edge of the wire mesh can be moved longitudinally with respect to the rope 10. Instead of this engagement method, the vertical support rope 10 and the mesh at the side edge of the wire mesh may be connected by a shackle (not shown). In this case, the shackle can be moved longitudinally with respect to the vertical support rope 10.

  As shown in FIG. 1, the rockfall guard fence 1 has a side rope 12 on the outer side of the end columns 3a, 3d, that is, on the side opposite to the side where the wire mesh 6 is located. The portion is coupled to the anchor 7 and the upper end portion is coupled to the upper shackle 11a as shown in FIG. This side rope 12 has the end struts 3a, 3d in the direction of the rock fall collision position due to the large tension generated in the upper support rope 5a when the rock fall protection fence 1 is impacted by the fall rock crash between the end struts 3a, 3d. So that the upright state of the end columns 3a and 3d is maintained.

  Next, the operation of the rock fall protection fence 1 according to the first embodiment will be described.

  FIG. 6 schematically shows a state in which the rockfall protection fence 1 receives an impact of the rockfall R falling from the mountain side in the direction of arrow Y in FIG. Since the wire mesh 6 is stretched on the valley side of the pillars 3a to 3d, as shown in FIG. 7, the whole is projected to the valley side in the state where the rock falls collide most, and the impact energy of the rock fall is It propagates through the wire mesh 6 from the collision location and spreads to the periphery.

The impact energy that has reached the upper and lower edges of the wire mesh 6 acts so that the component force draws these upper and lower edges on the upper and lower support ropes 5a and 5b to the upper and lower positions of the falling rock collision point. As a result, the upper and lower edges slide sideways in a curtain shape on the upper and lower support ropes 5a and 5b, whereby the wire mesh 6 is elastically deformed so that the entirety of the wire mesh 6 is gathered in the direction of the falling rock collision part to absorb energy. To prevent energy from concentrating on the rockfall collision point. (Note that in FIG. 6, the mesh of the metal mesh 6 is depicted as changing greatly in part, but in practice the size of each mesh is substantially uniform even though there are some differences. .)
The impact energy is further transmitted from the upper and lower edges of the wire mesh 6 to the upper and lower support ropes 5a and 5ba, and brings tensile force to both support ropes. When this tensile force exceeds the frictional force in the brake devices 8 and 9 and the loop pipes 8a and 9a are reduced in diameter, the frictional force and the reduced diameter of the loop pipe absorb a part of the impact energy. . The upper and lower support ropes 5a and 5b extend along with the diameter reduction of the loop pipes 8a and 9a. These upper and lower support ropes are laterally extended to the upper and lower support rope holders 4a and 4b. Since it is supported so as to be movable, it is curved and deformed in a state where it is pulled out to the valley side between the pillars 3b and 3c on both sides of the falling rock collision part corresponding to the length increase by the above stretching, and this curved deformation is the entire wire mesh. The degree of elastic deformation toward the falling rock collision point is further increased.

  The metal mesh 6 is engaged or connected so as to be movable in a vertical sliding manner with respect to the vertical support rope 10 also at the side edge portion thereof, and this configuration further increases the degree of freedom of elastic deformation of the entire metal mesh, A well-balanced elastic deformation is brought about.

  As described above, according to the present invention, the impact energy of the falling rock is not transmitted to the brake devices 8 and 9 at a stretch, but the deformation of the wire mesh 6 is successively performed in the process of transmitting the impact energy to the brake devices 8 and 9. With this configuration, energy is absorbed and dispersed each time, and this absorption and dispersion are performed in a well-balanced manner as a whole. As a result, the situation where the wire mesh 6 is partially broken is avoided, and only the wire mesh is used as a net, so that the net installation work is relatively easy and the falling rock protection fence is compared. Can be manufactured at low cost.

[Second Embodiment]
8 to 10 show a rock fall protection fence according to a second embodiment of the present invention. FIG. 8 is a front view of the left half portion of the rock fall protection fence. FIG. 9 is an enlarged perspective view of part A in FIG. FIG. 10 and FIG. 10 are enlarged scale perspective views of a portion B in FIG.

  The rockfall protection fence 50 according to the second embodiment is the same as that of the rockfall protection fence 1 according to the first embodiment except for the configuration of the connecting portions of the upper and lower support ropes and the wire mesh. These members are denoted by the same reference numerals, and detailed description thereof is omitted.

  According to the second embodiment, the rockfall protection fence 50 is a helical spring (helix) that is connected to the upper support rope 5a and the upper edge of the wire mesh 6 and to the lower support rope 5b and the lower edge of the wire mesh 6. Spring).

  As shown in FIG. 9, a helical spring 51 is wound around the upper support rope 5a in a loosely wound state, and this helical spring 51 is additionally provided in the vicinity of the columns 3a to 3d (FIG. 1). The helical spring 52 is attached in a state where it is entangled with the helical spring 51.

  The upper edge of the wire mesh 6 is engaged or connected to the helical spring 51 as shown in FIG. 9 except for the range in the vicinity of the column. In the range in the vicinity of the column, as shown in FIG. It is engaged with or connected to the helical spring 52.

  The helical springs 51 and 52 are made of a high-strength and high-elastic material such as spring steel, have a coil inner diameter that is approximately two to three times the outer diameter of the upper support rope 5a, and bend at the upper edge of the wire mesh 6. The coil pitch is substantially the same as the part pitch p.

  As shown in FIG. 9, the helical spring 51 is sequentially inserted for each coil in the mesh at the upper edge of the wire mesh 6 in an intermediate range other than the vicinity of the columns 3 a to 3 d. Both ends of the helical spring 51 are fixed to the upper support rope 5a in the vicinity of the end columns 3a, 3d (FIG. 1) by welding or other fixing means.

  Further, as shown in FIG. 10, the additional helical spring 52 is sequentially inserted for each coil in the mesh at the upper edge of the wire mesh 6 in the vicinity of the support column. Both ends of the additional helical spring 52 are fixed to the helical spring 51 by welding or other fixing means.

  The structure of the helical spring 51 and the additional helical spring 52 in the upper support rope 5a as described above, and the engagement or connection with the upper edge of the wire mesh 6 are the same for the lower support rope 5b. Is called.

  Next, the operation of the rock fall protection fence 50 according to the second embodiment will be described.

  As in the case of the rockfall protection fence 1 according to the first embodiment, when the rockfall collides with the wire mesh 6, the entire wire net protrudes to the valley side in a state where it bulges most at the rockfall collision location.

  The impact energy of the falling rocks is transmitted from the point where the rock falls into the wire mesh to the surroundings, and the upper and lower edges of the wire mesh 6 are subjected to the action of a force that is drawn toward the direction where the rock falls. The helical spring 51 slides sideways with respect to the upper and lower support ropes 5a and 5b, so that the upper and lower edges of the wire mesh 6 move laterally with respect to the upper and lower support ropes 5a and 5b.

  As shown in FIG. 11, the spiral springs are connected at the connection points between the upper and lower edges of the wire mesh 6 and the coils of the coil spring 51 along with the lateral movement, as shown in FIG. 51 is elastically stretched in the radial direction from the upper and lower support ropes 5a, 5b. Therefore, the wire mesh 6 is greatly increased in a balanced state by the lateral movement of the upper and lower edges and the elastic deformation of the helical spring 51. Deform.

  Further, in the vicinity of the columns 3a to 3d, the additional helical spring 52 is engaged with the helical spring 51 in an entangled state, and the upper and lower edges of the wire mesh 6 are the additional helical spring 52. As shown in FIG. 12, depending on the stress generated at each connecting portion between the upper and lower edges of the wire mesh 6 and the additional coil spring 52, the coil spring 51 and the additional coil spring 6 are connected to each other. The helical spring 52 is extended radially from the upper and lower support ropes 5a, 5b, and the wire mesh 6 is further enlarged near the support post by the combined extension of the helical spring 51 and the additional helical spring 52. It can be deformed.

  The deformation as shown in FIG. 11 and FIG. 12 occurs particularly conspicuously at and around the rockfall collision site.

  The action of the engagement between the side edge of the wire mesh 6 and the vertical support rope 10 and the action of the brake devices 8 and 9 are the same as in the case of the first embodiment.

  According to the rockfall protection fence 50 of the second embodiment, the wire mesh 6 can be further deformed as much as the helical springs 51 and 52 act as compared to the case of the first embodiment. This is performed in a well-balanced manner, and the effect of receiving the rockfall energy throughout the wire mesh is further increased.

  The present invention is not limited to the embodiment described above, and various modifications can be made without departing from the scope of the invention. For example, the pitch of the coils of the helical springs 51 and 52 may not be the same as the pitch of the meshes at the upper and lower edges of the wire mesh.

  Further, the rock fall protection fence of the first and second embodiments may be one span, and a plurality of spans may be connected side by side to form one long rock fall protection fence. In that case, the upper brake device 8 is disposed near the top of the end column 3a or 3d. In that case, you may arrange | position the upper brake device 8 inside the edge part support | pillar 3a or 3d, ie, the opposite side to the side in which the anchor 7 is provided.

It is a perspective view of the rock fall protection fence by a 1st embodiment of the present invention. It is a perspective view of the support | pillar which is a component of a rockfall protection fence. It is a perspective view of a brake device. It is a fragmentary perspective view which shows the connection part of the upper side support rope and wire mesh in the rock fall protection fence of FIG. It is sectional drawing by the VV line in FIG. It is a perspective view which shows a state when the rock fall protection device of FIG. 1 receives a rock fall. It is sectional drawing by the VII-VII line in FIG. It is a partial front view of the rock fall protection fence by 2nd Embodiment of this invention. It is an expansion perspective view of the A section in FIG. It is an expansion perspective view of the B section in FIG. FIG. 9 is a conceptual longitudinal cross-sectional view of a wire net portion having a single helical spring, similar to the cross section taken along the line XI-XI in FIG. 8 when the rock fall protection fence of FIG. FIG. 9 is a conceptual longitudinal sectional view of a wire mesh portion in which helical springs are doubled, similarly to the section taken along line XII-XII in FIG. 8.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Falling rock guard 2 Foundation 3, 3a-3d Support | pillar 4a Upper support rope holder 4b Lower support rope holder 5a Upper support rope 5b Lower support rope 6 Wire mesh 7 Anchor 8 Upper brake device 9 Lower brake device 10 Vertical support rope 11a Upper shackle 11b Lower shackle 12 Side rope 50 Falling rock protection fence 51 Vine spring 52 Additional helical spring

Claims (4)

Multiple struts erected at an interval on the inclined ground, upper and lower support rope holders provided at the upper and lower parts of each strut, and between the struts respectively held by these upper and lower support rope holders In the rockfall protection fence having the upper and lower support ropes spanned over and the net supported between these upper and lower support ropes and stretched between the columns,
The upper and lower support ropes are
The upper and lower support rope holders are supported so as to be laterally movable in the extending direction,
It is coupled to an anchor installed on the ground at a position outside the end column at the end of the plurality of columns,
When these support ropes are subjected to a tension of a predetermined magnitude or more, a brake device that allows the support ropes to extend while exerting a constant braking force is provided in a range from the vicinity of the end struts to the anchors. Have
The net
Formed of wire mesh,
Arranged on the trough side of the column,
An upper edge and a lower edge are attached to the upper and lower support ropes, respectively, so as to be slidable ,
A vertical support rope is mounted on the end column between the upper part and the lower part thereof,
A falling rock protection fence characterized in that a side edge of the wire mesh is attached to the vertical support rope so as to be slidable in the vertical direction .   The rock fall protection fence according to claim 1, wherein the wire mesh is supported by the upper and lower support ropes via a helical spring wound around the upper and lower support ropes. The helical spring is supported in the state where an additional helical spring is entangled in the vicinity of the column,
The upper and lower edges of the wire mesh engage the additional helical springs in the vicinity of the struts,
The rock fall protection fence according to claim 2 characterized by things. The end strut is supported by a side rope fixed to an anchor installed on the ground at the outer position so as to be prevented from tilting inward. The rock fall protection fence of any one of 1-3 .

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