JP2012172306A - Debris fall prevention facility, debris fall prevention structure and debris fall prevention method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a debris fall prevention technique capable of suppressing actions of a plurality of rock lumps dotted on a slope altogether.SOLUTION: By using a suspension net body 10 put on a slope and fixed to a plurality of rock lumps to suspend and support a static load, a suspension rope unit 20 suspending and supporting the suspension net body and having a load dispersing action, and a plurality of anchors 40 including high-order anchors and low-order anchors installed on the slope around the suspension rope unit to fix the suspension rope unit to the slope through connecting pulleys 30, while covering the plurality of rock lumps dotted on the slope with the suspension net, the static load acting on the suspension net body 10 is dispersed to the anchors 40 around to be supported through the suspension rope unit.

Description

  The present invention relates to a rockfall prevention facility, a rockfall prevention structure, and a rockfall prevention construction method that suppress various behaviors such as sliding or dropping of small and medium rock blocks of 30 t or less that are scattered on a slope.

Various rock fall prevention methods for suppressing various behaviors of rock masses are known.
In Patent Document 1, a lower end of a suspension rope is connected to a part of a rock mass via a lock bolt, and an upper end of the suspension rope is connected to an anchor provided on the slope side so that the rock mass is made up of a plurality of suspension ropes. A supporting rope method is disclosed. This method is suitable for large rock blocks with a rock mass exceeding 30 tf. In Patent Document 2, when a rock mass is suspended with a rope material, a pulley and a dispersion rope are used together to It has been disclosed to reduce anchor suspension loads.
The construction methods described in Patent Documents 1 and 2 are basically intended for a large rock mass exceeding approximately 30 tf.
In Patent Document 3, a slope having a plurality of rock blocks is covered with a net body including a rope member crossed vertically and horizontally at an interval of 0.5 m to 2 m and a wire net connected to the rope member, A covering type rope net construction method is disclosed in which the intersection of rope members constituting a body is fixed to a slope by an anchor, and movement of a plurality of rock blocks is suppressed by the anchor and the net body.

JP 2001-131923 A Japanese Patent No. 4564592 JP 2009-203681 A

The conventional rock fall prevention method has the following problems.
<1> When applying the method described in Patent Documents 1 and 2 for a single rock mass to a site where many small and medium-sized rock masses of 30 tf or less are scattered, the construction must be repeated for each rock mass. In addition, the burden is large in terms of construction cost and construction period.
For this reason, it is difficult to apply the construction methods described in Patent Documents 1 and 2 to a site where a large number of small and medium-sized rock blocks are scattered.
<2> Since the construction method described in Patent Document 3 is a structure that can finally withstand a heavy load with the strength of the anchor, the anchor must be installed deep in the ground as much as 4 to 5 m, and the rope The strength of the material must be calculated based on the largest rock mass.
Therefore, not only the construction cost is high and the construction period is long, but also the rock mass that can be restrained is limited to a small rock mass of 5 tf or less.
<3> The construction method described in Patent Document 3 restrains the displacement of the rock mass only by covering the mesh body.
Therefore, some rock blocks that are not in contact with the mesh body are likely to be displaced inside the mesh body. When some rock masses are displaced, the surrounding rock masses are displaced in a chain, so there is a problem in the effect of rock fall prevention.
<4> Workers use lifelines etc. to perform anchor work and net covering work, etc., but this type of site has a very high risk of sudden rock fall during work.
The conventional rock fall prevention method requires a long work time on the slope, which threatens worker safety. Under such circumstances, ensuring the safety of workers at work sites has become a major issue.

This invention is made | formed in view of the above point, The place made into the objective is to provide the rock fall prevention technique which can suppress the behavior of several rock mass collectively.
Specifically, an object of the present invention is to provide a rock fall prevention technique that can restrain displacement of a plurality of rock blocks scattered on a slope without imposing an excessive burden on an anchor and a rope.
Another object of the present invention is to provide a rock fall prevention technique capable of reducing the construction cost and the construction period.
Another object of the present invention is to provide a rock fall prevention technique capable of ensuring the safety of workers.
Another object of the present invention is to provide a rock fall prevention technique suitable for small and medium-sized rock blocks.

The present invention is a rock fall prevention technique for preventing the behavior of a plurality of rock masses scattered on a slope, and a suspension net that covers the slope and is fixed to the plurality of rock masses to suspend and support a static load. A suspension rope unit that suspends and supports the suspension net body, has a load distribution action, and is installed on a slope around the suspension rope unit, and an upper anchor that fixes the suspension rope unit to the slope via a connecting pulley; and A plurality of anchors including lower anchors are used, and a plurality of rock blocks scattered on the slope are covered with a suspension net, and the static load acting on the suspension net body is surrounded by the suspension rope unit. It is characterized by being dispersed and supported on the anchors.
The suspension rope unit can transmit the static load between a plurality of upper suspension ropes having a friction sliding load control device, an endless lower suspension rope connected to the suspension net, and the suspension ropes. A plurality of upper suspension ropes are disposed between the upper anchor and the load convergence device, and the lower suspension ropes are disposed between the load convergence device and the lower anchors. It is characterized by being slidably moored.
The suspension rope unit can transmit the static load between a plurality of upper suspension ropes having a friction sliding load control device, an endless lower suspension rope connected to the suspension net, and the suspension ropes. A plurality of upper suspension ropes are disposed between the upper anchor and the load convergence device, and the lower suspension ropes are disposed between the load convergence device and the lower anchors. It is characterized by being slidably moored.
Furthermore, the present invention is characterized in that an upper part of each upper suspension rope and a part of each lower suspension rope of a plurality of suspension rope units installed on the upper and lower sides and right and left sides of the slope are fixed to be shared by the anchor.

According to the present invention, at least one of the following effects can be obtained.
(1) The suspension net and rope unit cooperate to distribute and transmit the static load of multiple rock blocks scattered on the slope to the surrounding anchors. Can be prevented.
In addition, the rock mass is not simply covered with the mesh body, but is fixed to the suspension mesh body, so that the displacement of each rock mass can be reliably restrained.
(2) It becomes possible to disperse and support the static load of the rock mass acting on the suspension net through the suspension rope unit having the load dispersion action on the surrounding anchors.
Therefore, the static load borne by each anchor can be reduced.
(3) Since the lower suspension rope that constitutes the suspension rope unit is slidably moored to the lower anchor, a uniform load always acts on the lower suspension rope over the entire length thereof.
Therefore, even if a static load acts on a part of the lower suspension rope, it is possible to prevent an excessive load from acting on one of the lower suspension rope and the lower anchor and damage.
(4) In the present invention, the anchor alone can be reduced in size as compared with the conventional one due to the load dispersion action by the suspension rope unit.
Furthermore, when the anchors to which the plurality of suspension rope units are fixed are shared, the number of anchors installed can be greatly reduced as a whole.
Therefore, the workability can be improved as compared with the conventional anchor work, and the construction period and cost can be greatly reduced.
(5) Not only can the anchor work be done in a short period of time, but after the slope is covered with a suspension net body to ensure a certain level of safety, subsequent work such as installation work of the suspension rope unit can be performed.
Therefore, compared with the prior art, it is possible to greatly reduce the time during which the worker is exposed to danger and to perform construction in a safe working environment even during work.
(6) An economical rock fall prevention technique suitable for slopes dotted with small and medium-sized rock blocks can be provided.
(7) When the upper suspension rope has the load control device, it is possible to eliminate the mounting error of each of the multiple ropes.
Furthermore, when a plurality of upper suspension ropes are arranged, the load control action of the load control device can eliminate the tension difference between the upper suspension ropes. Static load can be transmitted evenly.

Schematic of the rock fall prevention facility according to the present invention Sectional view of II-II in FIG. Sectional view of hanging net and rock mass fixing part Perspective view of hanging rope unit Sectional view of VV in FIG. Explanatory drawing of load control device Model diagram for explaining the action of the load control device alone Model diagram for explaining the action of a pair of load control devices

  Embodiments of the present invention will be described below with reference to the drawings.

<1> Model diagram of rockfall prevention facility FIGS. 1 and 2 show an outline of the rockfall prevention facility according to the present invention, and FIG. 3 shows a load distribution model of the rockfall prevention facility.

  The rock fall prevention facility is a facility for preventing the behavior of a plurality of rock blocks R scattered on the slope G, and the suspension net body 10 that covers the slope G and is fixed to the plurality of rock blocks R; 10 and a plurality of anchors 40 for fixing the suspension rope unit 20 to the inclined surface G via a connecting pulley 30.

The rock fall prevention facility is a facility that has both the excellent characteristics of the covered rope net method and the suspension rope method, and a part of the suspension net body 10 is fixed integrally to the rock mass R, and the suspension rope unit 20 is attached to the surrounding anchor. The behavior of the rock masses R scattered on the slope G can be prevented by lifting the suspension net body 10 while mooring at 40.
Further, the combination of the pulley and the multiple ropes is adopted in order to avoid an excessive load burden on the anchor 40 and the suspension rope unit 20.
In the present invention, the term “hang” refers to a state in which the suspension net 10 is stretched without a large slack.

<2> Suspension net body The suspension net body 10 is a wire net, a wire mesh, or a net-like material obtained by polymerizing these, and the parts that are divided and carried on site are assembled into a single net as a whole.
The suspension net 10 is not simply installed for the purpose of covering the plurality of rock masses R.
As will be described later, a plurality of rock masses R are regarded as one continuous structure by fixing a part of the suspension net body 10 together with a plurality of rock masses R scattered on the slope. Functions to support static loads.

<3> Connection pulley The connection pulley 30 is a pulley for connecting the suspension ropes 21 and 22 constituting the suspension rope unit 20 to the anchor 40. For example, as shown in FIGS. It is composed of U-shaped attachment hooks 33 connected to both ends of 32.
The pulley 31 is used to reduce the sliding resistance of the suspension ropes 21 and 22.
The number of pulleys 31 pivotally supported on the support shaft 32 is the same as the number of ropes to be moored, and includes single, double, triple, or more.
In order to connect the connecting pulley 30 to the anchor 40, the attachment hook 33 is inserted into the connection hole 42 of the dispersion plate 41 provided integrally with the anchor 40 and hooked.

<4> Anchors As shown in FIGS. 1 and 2, a plurality of anchors 40 are constructed at predetermined intervals in the vertical and horizontal directions of the slope G. In the present invention, one set of the hanging rope unit 20 is supported by at least four anchors 40 in all directions. As the anchor 40, a known anchor body such as a self-piercing anchor can be applied, and is appropriately selected according to the situation at the site.

As shown in FIG. 4, a dispersion plate 41 is integrally attached to the head of each anchor 40, and the suspension rope unit 20 is connected to the four sides of the suspension rope unit 20 via the connection pulley 30 connected to the dispersion plate 41. Connect to the anchor 40.
A plurality of connection holes 42 are formed in the periphery of the dispersion plate 41, and the plurality of connection pulleys 30, the auxiliary ropes 11, and the like can be connected through the connection holes 42.

The upper structure of the anchor 40 will be described with reference to FIG. 5. The anchor 40 is driven into the ground, and the reinforcing tube 43 is externally installed in a range of about 40 cm from the ground surface. Further, a disc-like dispersion disc 41 is inserted through the reinforcing pipe 43 protruding to the ground surface. The coupler 44 is put on the top of the dispersion plate 41, and the fixing nut 45 is attached to the head of the rod 43 protruding from the coupler 44, so that the dispersion plate 41 is attached integrally to the head of the anchor 40.
The mounting structure of the dispersion plate 41 described above is an example, and a known mounting means can be applied.

<5> Hanging rope unit FIG. 4 shows a model diagram of the hanging rope unit 20.
The suspension rope unit 20 is a unit for distributing and transmitting a static load applied to the suspension net body 10 to the plurality of anchors 40. The suspension rope unit 20 includes a pair of left and right upper suspension ropes 21 arranged in an inverted C shape, and approximately two. A lower suspension rope 22 having an endless structure disposed in the form of an equilateral triangle and a load converging device 50 disposed between the suspension ropes 21 and 22 are provided.

<5.1> Load Converging Device The load converging device 50 is a device for equalizing the static load applied to the lower suspension rope 22, and pivotally supports triaxial pulleys 52 to 54 between a pair of substrates 51. . The upper two pulleys 52 and 53 are located in a horizontal row, and the lower pulley 54 is located at the lower center of the upper pulleys 52 and 53.

<5.2> Upper Suspension Rope The upper suspension rope 21 is routed between the upper anchors 40 ₁ , 40 ₂ and the upper two pulleys 52, 53 of the load converging device 50, and is statically loaded on the load converging device 50. It is a rope material for evenly distributing the dynamic load to the higher anchors 40 ₁ and 40 ₂ .
The upper suspension rope 21 is composed of an endless loop in which, for example, one rope material is used and both ends thereof are connected so as not to be separated.
The upper suspension rope 21 includes two forms of a complete loop whose overall length does not change and an incomplete loop whose loop length slightly changes via the load control device 25. In this example, the upper suspension rope 21 is the latter. Will be described.

In this example, the case where the number of ropes constituting the upper and lower suspension ropes 21 in the left and right groups is two (double) ropes 21a and 21b will be described, but one or three or more ropes may be used.
In some cases, the upper part of the upper suspension rope 21 is directly fixed to the head of the anchor 40 as shown in FIG.

<5.3> Load Control Device The load control device 25 provided at both ends of the ropes 21a and 21b constituting the upper suspension rope 21 is made uniform by equalizing the tension of the ropes 21a and 21b. This is a device for controlling the load applied to the ropes 21 a and 21 b to be smaller than the breaking strength of the rope and the breaking load of the anchor 40 as well as eliminating the influence of the attachment error at the time of tensioning 21.
In other words, the load control device 25 functions as a limiter for preventing the ropes 21 a and 21 b from being broken and preventing the anchor 40 from being broken.

The friction sliding load control device 25 illustrated in FIG. 6 will be described. The load control device 25 is a pair of constraining plates formed into a cylindrical shape by bending two strips so that the rope 21a (21b) can be gripped. 26, 26, and a plurality of sets of bolts 27 and nuts 28 that pass through and tighten the bottom portions of the pair of restraining plates 26, 26.
The restraint plate 26 is configured to be able to grip the rope 21a (21b) by bending spring steel into a circular arc shape with a diameter smaller than that of the rope 21a (21b) and closing a pair of skirts.

  When the frictional forces of the two restraining plates 26 and 26 holding both ends of each rope 21a (21b) are set to be equal to each other and a tension difference is generated between the ropes 21a and 21b due to a static load. One of the ropes 21a and 21a (21b and 21b) slides between the restraining plates 26 and 26 until the tensions of the ropes 21a and 21a (21b and 21b) become equal.

In the present invention, since the load of the rock mass acting on the rope is not a dynamic load but a static load, the sliding occurs until the tension difference between the ropes 21a and 21b is eliminated and becomes equal. Sliding does not occur after the tension difference between 21a and 21b disappears.
The load control device 25 is not limited to the above-described form. When a predetermined tension is applied to both ends of each rope 21a (21b), the rope length is slightly extended to tension both the ropes 21a and 21b. Any structure that can be made equal can be used.

<5.4> Lower Suspension Rope As shown in FIGS. 4 and 8, the lower suspension rope 22 is a rope member for transmitting the static load of the rock mass acting on the suspension net body 10 to the load converging device 50. Are anchored so as to be slidable (movable) in the form of a substantially isosceles triangle between the anchors 40 ₃ , 40 ₄ and the lower pulley 54 of the load converging device 50.
The endless lower suspension rope 22 does not include the load control device 25, and the loop length does not change.
Similarly to the upper suspension rope 21, the lower suspension rope 22 is composed of one or more multiple ropes, and in this example, is composed of two ropes 22a and 22b.

The lower suspension rope 22 has a substantially isosceles triangle having a bottom side and two oblique sides, and at least a rope corresponding to the bottom side is connected to the suspension net body 10 so that a load can be transmitted.
As the connection means, a rope can be inserted through the mesh of the suspension net 10, or a connection tool such as a connection coil can be used.

The reason why the lower suspension rope 22 is movably moored is that the static load acting on the bottom of the lower suspension rope 22 is evenly distributed on the two oblique sides of the lower suspension rope 22.
The reason for mooring to the connecting pulley 30 having a substantially isosceles triangle is to avoid an excessive load burden due to the lower anchors 40 ₃ and 40 ₄ .
If both lower corners of the lower suspension rope 22 are moored to a rod-shaped fixing member (not shown), a load obtained by doubling a static load acting on the bottom of the lower suspension rope 22 acts on the rod-shaped fixing member. It is.

[How to build a rockfall prevention facility]
Next, a method for constructing a rockfall prevention facility will be described.

<1> Anchor Construction As shown in FIGS. 1 and 2, a plurality of anchors 40 are constructed in the vertical and horizontal directions of the slope G where a plurality of rock masses R are scattered, and the dispersers shown in FIG. 41 is installed. The anchor 40 is installed on the slope G avoiding the rock mass R.
In the present invention, a small-scale anchor can be adopted as the anchor 40 in accordance with the load distribution effect by the hanging rope unit 20.
That is, the scale of the anchor alone can be changed to a smaller one as compared with the conventional method.
Therefore, it is possible to use small-scale anchors that do not require the above work from large-scale anchors that required the construction of heavy equipment for drilling, temporary scaffolding, etc., so that workability can be improved compared to conventional anchor works. The construction period and cost can be greatly reduced.

<2> Laying of the Suspension Net Next, the auxiliary rope 11 connected between the uppermost side of the hoist 10 and the uppermost anchor 40 is developed by spreading the hoist 10 that has been carried to the site and covering the slope G. The suspension net body 10 is temporarily supported through.

<3> Fixing of rock mass As illustrated in FIG. 3, a lock bolt 13 such as a steel bar is inserted into a hole 12 drilled in the rock mass R, and the suspension net 10 is positioned between the mounting plates 14. And the nut 15 is screwed onto the head of the lock bolt 13 through which the mounting plate 14 is penetrated, and the suspension net 10 is integrated with each rock block R.
By integrating the suspension net body 10 with the plurality of rock blocks R scattered on the slope, the plurality of rock blocks R can be formed as one continuous structure.

The fixed position and the fixed number are appropriately selected in consideration of the shape and size of the rock mass R.
Moreover, the fixing means to the rock mass R is not limited to the lock bolt 13, and a well-known fixing means is applicable.
If a rock bolt 13 is used as a fixing means for the rock mass R instead of a general anchor, vibration to the rock mass R can be reduced, so that the drilling operation can be performed more safely.
Reference numeral 16 in the figure denotes a consolidated material filled in the holes 12.

<4> Mooring work of the suspension rope unit Next, the suspension rope unit 20 is routed to and anchored to the plurality of anchors 40, and the ropes corresponding to the bottom side and the oblique side of the lower suspension rope 22 are connected to the suspension net body 10. To do.

The installation structure of the suspension rope unit 20 will be described in detail with reference to FIG. 4. The upper ends of the upper suspension ropes 21 each having the load control device 25 are connected to the upper anchors 40 ₁ , 40 ₂ via the connecting pulley 30. And the upper part of each upper suspension rope 21 is moored to the upper two pulleys 52 and 53 of the load converging device 50, respectively.

The upper part of the endless lower suspension rope 22 is moored to the lower pulley 54 of the load converging device 50, and the lower part of the lower suspension rope 22 is moored to the lower anchors 40 ₃ and 40 ₄ via the connecting pulley 30.
A rope corresponding to the bottom of the lower suspension rope 22 is connected to the suspension net 10 so that a load can be transmitted.
As the connection means, a rope can be inserted through the mesh of the suspension net 10, or a connection tool such as a connection coil can be used.

As described above, a pair of upper suspension ropes 21, 21 are positioned in an inverted C shape on the upper side while being anchored to the _four surrounding anchors 40 ₁ to 40 ₄ , and the lower suspension rope is in the form of a substantially isosceles triangle on the lower side. 22 is positioned, and the suspension rope unit 20 is installed with the load converging device 50 interposed between the suspension ropes 21 and 22.
When installing a plurality of suspension rope units 20 vertically and horizontally, all the anchors 40 except the highest anchor 40 can be shared as the fixing destinations of the suspension ropes 21 and 22, greatly increasing the number of anchors 40 installed. Can be reduced.
Therefore, the construction cost can be reduced and the construction period can be shortened.

  Furthermore, in the present invention, the suspension rope unit 20 can be installed in a short time in a safe environment in which the entire slope G where the plurality of rock blocks R are scattered is covered with the suspension net 10 and temporarily supported. Work safety.

[Method of preventing rock mass behavior]
Next, a method for preventing rock mass behavior by the rock fall prevention facility will be described.

<1> Transmission of Static Load Static loads of a plurality of rock masses R scattered on the slope G are transmitted to the rock mass R and the fixed suspension net 10.
Most of the static load transmitted to the suspension net 10 is transmitted to the upper anchors 40 ₁ and 40 ₂ via the lower suspension rope 22, the load converging device 50 and the upper suspension rope 21 that constitute the suspension rope unit 20. Has been supported.
That is, the load acting on the lower suspension rope 22 is collected by the load converging device 50 and is evenly distributed to the upper suspension rope 21.
A part of the static load transmitted to the suspension net 10 is transmitted to and supported by the lower anchors 40 ₃ and 40 ₄ via the lower suspension rope 22 constituting the suspension rope unit 20.

In the present invention, the suspension net body 10 and the suspension rope unit 20 cooperate to disperse and transmit the static loads of the plurality of rock blocks R scattered on the slope G to the surrounding anchors 40. Therefore, the plurality of rock blocks Can be prevented collectively.
Moreover, since the rock mass R is not simply covered with the mesh body but is fixed to the suspension net body 10, the displacement restraining effect of each rock mass R is enhanced.

<2> Load Dispersion Action of Suspension Rope Unit A static load dispersion action by each pair of suspension rope units 20 will be described.
Since the lower suspension rope 22 constituting the suspension rope unit 20 is movably moored to the load converging device 50 and the connecting pulley 30, an equal load always acts on the lower suspension rope 22.
Therefore, even if a static load acts on the bottom side of the lower suspension rope 22, it is evenly distributed on the two oblique sides of the lower suspension rope 22, so a part of the lower suspension rope 22 and the lower anchor 40 ₃ , 40 ₄ is not damaged by an excessive load acting on one of them.

The static load collected at the top of the lower suspension rope 22 having a substantially isosceles triangle is transmitted to the pair of upper suspension ropes 21 and 21 through the load converging device 50, and further via the upper suspension unit 21 to the upper anchor. 40 ₁ and 40 ₂ are evenly distributed and supported.
Accordingly, the upper anchors 40 ₁ and 40 ₂ only have to bear half of the static load P, and the load burden on the anchor 40 can be reduced.

  Furthermore, in the present invention, when the suspension ropes 21 and 22 are composed of multiple ropes, the load burden per rope can be reduced, so that not only a small-diameter rope can be used but also the rope is moored as the rope diameter decreases. Since the pulley can also be designed to have a small diameter, the connecting pulley 30 and the load converging device 50 can be manufactured at low cost and at a low cost.

<3> Operation of Load Control Device The operation of the load control device 25 provided on the upper suspension rope 21 will be described in detail with reference to FIGS.
FIG. 7 is a developed view of the arrangement of the upper suspension rope 21 composed of two ropes 21a and 21b. The two ropes 21a and 21b are a pulley 31 connected to an upper anchor 40 and a load converging device 50. It is stretched between the upper pulley 52 (53).

Although the frictional force (upper limit of static load) of the load control device 25 provided on each rope 21a, 21b can be set equal, the two ropes 21a, 21b are in the same state (same tension, same length) at the site. Tensioning is difficult, and there is a difference in length and tension between the ropes 21a and 21b.
(A) of the figure shows a state in which the left rope 21a is stretched in a slightly slack state with respect to the right rope 21b.

In this state, when the static load P due to the rock mass acts on the two ropes 21a and 21b, the static load P is applied only to the right rope 21b, and therefore the right rope 21b and the right load control. A slight sliding with the device 25 occurs.
When the loop length and tension of the left and right ropes 21a and 21b become equal, the sliding on the right side stops.

  FIG. 7B shows a state in which the tension lengths and tensions of the left and right ropes 21a and 21b are adjusted equally. In this state, the left and right ropes 21a and 21b evenly support the static load P in a distributed manner. It will be.

The load control device 25 not only eliminates the error of the rope length when the upper suspension ropes 21 and 21 are stretched, but also makes the load applied to the ropes 21a and 21b smaller than the breaking strength of the rope and the breaking load of the anchor 40. Can be controlled.
Therefore, even if a static load P greater than the design value is applied, the ropes 21a and 21b and the anchor 40 can be prevented from being damaged by the load control action of the load control device 25.

Further, as shown in FIG. 8, the left and right upper suspension ropes 21, 21 connected to the upper anchors 40 ₁ , 40 ₂ have a load control device 25.
Therefore, the tension control difference between the left and right upper suspension ropes 21 and 21 can be eliminated by the load control action of the load control device 25.
Therefore, even if the arrangement position and the arrangement height of the anchor 40 installed on the slope are slightly deviated, it is possible to maintain the uniform transmission action of the static load by the pair of upper suspension ropes 21 and 21.
When the upper suspension rope 21 is a pair as in this example, the upper anchors 40 ₁ and 40 ₂ only need to bear a static load of P / 2.

In FIG. 1, the static load of the rock mass R scattered on the slope G is assumed to be approximately 0.1 to 30.0 tf.
Self-drilling anchors 40 having an allowable yield strength of 200 KN are constructed at intervals of 3 m in width and 10 m in length.

  As the suspension net 10, a wire net having a diameter of 5 mm 100 × 100 and an overall size of 3 m × 10 m is used. The joint of the wire mesh is connected using a connecting coil or the like.

  For the lock bolt 13 for fixing the suspension net 10 to the rock mass R, a deformed steel bar D16 is used and fixed with a resin adhesive, and the pulling strength is 50 kN or more.

  For the upper suspension rope 21 and the lower suspension rope 22, wire ropes having a diameter of 12 mm 6 × 24 (breaking load 65 KN) are used. (65KN × 2 × 2).

The upper limit of the static load of the load control device 25 is set to 40KN.
Therefore, the load control device 25 can control the load applied to the upper suspension rope 21 on one side and the upper anchor 40 to 40 KN × 2 turns, that is, 80 KN or less.
Therefore, the rock fall prevention facility according to the present invention is suitable for a rock block of medium to small scale (generally less than 30 tf).

[Other variations]
The upper suspension rope 21 constituting the suspension rope unit 20 is not limited to the left and right two sets, and may be one set or three or more sets.
In the latter case, the load burden of the upper anchor 40 can be further reduced.

In the above description, the lower suspension rope 22 is arranged in a substantially triangular shape between the load converging device 50 and the lower anchors 40 ₃ and 40 _4. However, a plurality of lower pulleys of the load converging device 50 are provided in parallel. The lower suspension rope 22 may be arranged in a substantially trapezoidal shape or a substantially rectangular shape.
In short, the lower suspension rope 22 may be slidably disposed in a polygonal shape between the load converging device 50 and the lower anchors 40 ₃ and 40 ₄ .

G ··· Slope R ··· Rock mass 10 ··· Suspension net 11 ··· Auxiliary rope 13 ··· Lock bolt 14 ··· Mounting plate 20 ----- hanging rope unit 21 ..... upper hanging rope 22 ..... lower hanging rope 30 ----- connecting pulley 40 (40 ₁ to 40 ₄₎ ... anchor 41 .. ... Dispersion panel 50 ... Load converging device

Claims (8)

A rockfall prevention facility that prevents the behavior of multiple rock blocks scattered on the slope,
A suspension net that covers the slope and is fixed to a plurality of rock blocks to support static loads.
A suspension rope unit that supports and suspends the suspension net, and has a load dispersion action;
A plurality of anchors including an upper anchor and a lower anchor that are installed on a slope around the suspension rope unit and fix the suspension rope unit to the slope via a connecting pulley;
While covering a plurality of rock blocks scattered on a slope with a suspension net, the static load acting on the suspension net body via the suspension rope unit is dispersed and supported on surrounding anchors, To
Rock fall prevention facility. 2. The suspension rope unit according to claim 1, wherein the suspension rope unit includes a plurality of upper suspension ropes having a friction sliding load control device, an endless lower suspension rope connected to the suspension net, and the static rope between the suspension ropes. A load converging device that is interposed so as to be able to transmit a dynamic load,
Arranging the plurality of upper suspension ropes between the upper anchor and the load converging device;
A rock fall prevention facility, wherein the lower suspension rope is slidably moored between a load converging device and a lower anchor. A rock fall prevention structure that prevents the behavior of multiple rock blocks scattered on the slope,
A suspension net that covers the slope and is fixed to a plurality of rock blocks to support static loads.
A suspension rope unit that supports and suspends the suspension net, and has a load dispersion action;
A plurality of anchors including an upper anchor and a lower anchor that are installed on a slope around the suspension rope unit and fix the suspension rope unit to the slope via a connecting pulley,
While covering a plurality of rock blocks scattered on a slope with a suspension net, the static load acting on the suspension net body via the suspension rope unit is dispersed and supported on surrounding anchors, To
Rock fall prevention structure. 4. The suspension rope unit according to claim 3, wherein the suspension rope unit includes a plurality of upper suspension ropes having a frictional sliding load control device, an endless lower suspension rope connected to the suspension net, and the static rope between the suspension ropes. A load converging device that is interposed so as to be able to transmit a dynamic load,
Arranging the plurality of upper suspension ropes between the upper anchor and the load converging device;
A falling rock prevention structure, wherein the lower suspension rope is slidably moored between a load converging device and a lower anchor. In Claim 4, arrange | positioning the said upper suspension rope unit in a reverse C shape between a high-order anchor and a load convergence apparatus,
A falling rock prevention structure, wherein the lower suspension rope is arranged in a substantially triangular shape between a load converging device and a lower anchor.   The falling rock according to claim 4 or 5, wherein a part of each upper suspension rope and a part of each lower suspension rope of the plurality of suspension rope units installed on the upper and lower sides and the left and right sides of the slope are fixedly shared by the anchor. Preventive structure. A rock fall prevention method that prevents the behavior of multiple rock blocks scattered on a slope,
A suspension net that covers the slope and is fixed to a plurality of rock blocks to support static loads.
A suspension rope unit that supports and suspends the suspension net, and has a load dispersion action;
A plurality of anchors including an upper anchor and a lower anchor that are installed on a slope around the suspension rope unit and fix the suspension rope unit to the slope via a connecting pulley,
While covering multiple rock masses scattered on the slope with a suspension net,
The static load acting on the suspension net via the suspension rope unit is distributed and supported by surrounding anchors,
Rock fall prevention method. The suspension rope unit according to claim 7, wherein the suspension rope unit includes a plurality of upper suspension ropes having a friction sliding load control device,
A lower suspension rope having an endless structure connected to the suspension net;
A load converging device interposed between the suspension ropes so that the static load can be transmitted;
Arranging the plurality of upper suspension ropes between the upper anchor and the load converging device;
A falling rock prevention method, wherein the lower suspension rope is slidably moored between a load converging device and a lower anchor.

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