JP2020070647A - Pillar, upper-stage horizontal rope and hanging rope in pocket type rockfall protection net - Google Patents

Abstract

To provide a pocket type rockfall protection net provided as a rockfall protection facility, in which a pillar that secures an opening is likely to be damaged by direct impact of rockfall; in such a site, it is necessary to consider the installation position and arrangement interval of the pillars as a measure to avoid the direct impact of rockfall.SOLUTION: With respect to a conventional type pocket type rockfall protection net comprising a plurality of pillars, a pillar suspension rope for supporting the standing state of the pillars, an upper-stage horizontal rope laid between the pillars and forming an opening with respect to a slope, and a net portion, a pocket type rockfall protection net is provided which is further provided with a horizontal rope hanging rope that is connected so as to hang the upper-stage horizontal rope.SELECTED DRAWING: Figure 1

Description

  BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pocket-type rockfall protection net, and to installation of a pillar, an upper horizontal rope, and a suspension rope that secures an opening for rockfall and at the same time receives a shock from rockfall.

  As measures against rockfall on slopes, there are rockfall prevention that prevents rockfall at the source of rockfall and rockfall protection that waits for the rockfall and stops its movement or guides it downward or sideways. The facilities installed in etc. are rockfall prevention facilities and rockfall protection facilities.

  One of the rockfall protection facilities is a pocket-type rockfall protection net. This is to cover the lower part of the slope with a mesh member formed of a wire rope and a wire mesh, and to provide an opening (pocket) for taking in rockfall from the upper part of the slope. The rock fall captured from this opening is guided downward through the space between the slope and the net. A plurality of columns are installed in order to secure a predetermined height so that the rockfall is captured without jumping over, and an opening is provided between the upper horizontal rope installed near the top of the column and the slope. Supporting the support from above the slope is a support suspension rope, as shown in FIG.

  The columns are generally installed on the same contour line at intervals of about 3 m, but since the intervals of installation are relatively small with respect to the size of the rockfall, they may be damaged by being directly hit by the rockfall. In such a site, the installation position of the support and the support structure may be reviewed. In addition, when a disaster occurs in which the pillars are damaged, the original form is basically restored, but it may be difficult to take measures to avoid a direct hit of a rockfall after the restoration.

  Regarding the reinforcement of the facility of the pocket-type rockfall protection net, there is a proposal of an invention (Japanese Patent Laid-Open No. 2016-121481) that enhances the absorption efficiency of impact energy by reinforcing a rope and a technique (Japanese Patent No. 5706990) related to a raised structure of a pillar. In addition, there is a high-energy absorption protection network ("Handbook for Countermeasures against Rockfall" p91) in the pocket-type rockfall protection network, and there is also a construction method in which the column spacing is increased.

JP, 2016-121481, A Japanese Patent No. 5706990

Japan Road Association "Handbook for Falling Rocks" December 2017

  The problem to be solved is to improve the function of the pocket-type rockfall protection net as a rockfall protection facility in consideration of economical efficiency, and a pillar that secures an opening, a suspension rope and a pillar that suspends the pillar are provided. This is a pocket-type rockfall protection net that can widen and change the arrangement interval of the pillars while trying to disperse and absorb rockfall energy with respect to the upper horizontal rope that it supports.This method is used when designing new construction for a pocket-type rockfall protection net. It can also be used for.

A pocket-type rockfall protection net,
A plurality of columns that are axially supported by the foundation provided on the slope and stand upright,
A column suspension rope that has one end hooked to a fixed portion on the upper slope of the ground on which the column is installed and the other end connected at the upper portion of the column, and that suspends the standing state of the column. ,
Both ends are hooked to different fixing parts, and an upper stage horizontal rope installed between the plurality of struts in the middle part,
A plurality of vertical ropes hanging from the opening formed between the upper horizontal rope and the slope and hanging from the upper horizontal rope, a plurality of horizontal ropes connected to the plurality of vertical ropes, and a plurality of the horizontal ropes. A mesh portion including a wire mesh stretched on a horizontal rope or a vertical rope of
A horizontal rope suspension rope having one end hooked to a fixed portion of the upper slope of the ground where the upper horizontal rope is installed and the other end connected to suspend the upper horizontal rope,
Pocket type rockfall protection net with.

The pocket-type rockfall protection net,
The tension of the horizontal rope suspension rope was set so that the direction of the resultant force of the load generated on the upper horizontal rope due to the weight of the upper horizontal rope and the weight of the mesh portion and the tension of the horizontal rope suspension rope becomes the longitudinal direction of the column. Pocket type rockfall protection net.

The pocket-type rockfall protection net,
Between the fulcrum calculated by converting the load or the resultant force per unit length of the upper horizontal rope and the force acting per unit length of the upper horizontal rope and the horizontal tensile force acting on the upper horizontal rope The pocket-type rockfall protection net used in the design of the column, the upper horizontal rope, or the horizontal rope suspension rope as a curve drawn by the upper horizontal rope between the columns in the vertical direction or the direction in which the resultant force acts.

  Regarding a pocket type rockfall protection net consisting of conventional columns, column suspension ropes, upper horizontal ropes and nets, the horizontal tensile force is set to a predetermined value without changing the load and the clearance of the opening. A pocket-type rockfall protection net having a new column interval and column height for expanding the columns, and equipped with the horizontal rope suspension rope of the present invention.

A method of designing a pocket type rockfall protection net with a horizontal rope suspension rope according to the present invention, comprising:
Calculating or setting the force acting per unit length of the resultant force;
Calculating or setting the horizontal tensile force,
Calculating a catenary curve from the force acting per unit length and the horizontal tensile force,
A method of designing a pillar interval, a pillar height, or a pillar structure between pillars provided with.

  In order to reduce the possibility of direct hitting of rockfall on the pillar without installing external force for the installation of the pillar and the upper horizontal rope that form the opening of the conventional pocket type rockfall protection net, the installation interval of the pillar is reduced. Provides a new pocket-type rockfall protection net that can be expanded. The horizontal rope suspension rope added to this new pocket-type rockfall protection net suppresses the suspension of the rope by directly hoisting the upper horizontal rope that is the upper limit of the opening, and the upper horizontal rope is trapped by the trapped rocks. Bear the impact force applied to the rope. In the present invention, with respect to the horizontal rope suspension rope, pocket type rockfall protection by a rational tension setting method, a new arrangement of columns due to the addition of the horizontal rope suspension rope, a height and a tension of the upper horizontal rope are designed. It presents a web.

FIG. 1 is an explanatory view of a pocket-type rockfall protection net provided with a horizontal rope suspension rope according to the present invention. (Example 1, Example 2) FIG. 2 is a front view of a pocket type rockfall protection net according to the present invention and an explanatory view showing a connecting fitting and the like. (Example 1, Example 2) FIG. 3 is an explanatory diagram of the upper horizontal rope and the horizontal rope suspension rope. (Example 2) FIG. 4 is an explanatory diagram of a resultant force direction applied to the upper horizontal rope. (Example 2) FIG. 5: is explanatory drawing of application to a catenary curve and the upper stage horizontal rope of this curve. FIG. 6 is an explanatory view when the upper horizontal rope loses the fulcrum (Examples 3 and 4). FIG. 7: is explanatory drawing regarding the raising of the pocket type rockfall protection net which has a horizontal rope hanging rope (Example 4, Example 5). FIG. 8 is a general view of a conventional pocket-type rockfall protection net. FIG. 9: is explanatory drawing of the support of a pocket type rockfall protection net.

    In the pocket-type rockfall protection net 1, as shown in FIG. 8, an opening (pocket) 13 serving as an entrance of the rockfall 12 is provided by the support column 2 and the upper horizontal rope 3. In general, the columns are installed at regular intervals on the contour line of the slope, and the height thereof is about 3 to 5 m in consideration of the expected size of rock fall and the jumping amount. As shown in FIG. 9, the support pillar is pivotally supported by the foundation portion 15 provided on the slope, and the tension of the support suspension rope 41 connected at the upper portion of the support pillar portion 21 makes it approximately 90 degrees with respect to the slope. It is standing. The support column is connected to the upper horizontal rope 3 near the top and forms an opening. The vertical ropes 51 hanging from the columns and the upper horizontal ropes connect the horizontal ropes 52 and the wire nets 53 to form the net portion 5 formed on the lower side of the slope, receive rockfalls received from the openings, and absorb the impact. , Guide to the lower part of the net.

  The clearance 14 of the opening 13 in the present invention is a clearance between the slope 11 and the upper horizontal rope 3 as shown in FIG. 4, and must be a clearance that can be captured in consideration of jumping of the rock fall 12. The column suspension rope 41 in the present invention is a rope that suspends the column by being coupled to the column as described above, and the horizontal rope suspension rope 42 is coupled to the upper stage horizontal rope as shown in FIG. This is a rope that suspends the upper horizontal rope. These two types of suspension ropes and upper horizontal ropes play a role of ensuring the clearance of the opening, capturing the rockfall at the opening, and absorbing the impact energy of the rockfall that collides with the net.

  The rope in the present invention is a wire rope, and the fixing portion 16 for hooking various ropes is an anchor that plays a role of fixing to the natural ground 11 and a terminal treatment such as a winding grip (FIG. 2 (5)). It is provided with a fitting for hooking the rope 35 (illustration is omitted). As shown in FIG. 9, the foundation portion 15 of the present invention is provided on the slope 11 so as to erect the pillar 2, and anchors that play a role of fixing to the natural ground and the pillar portion under the pillar pillar portion 21 are used as shafts. It has a rotating shaft for supporting and a bearing.

The catenary curve in the present invention is a curve also called a suspension curve, and is a theoretical curve obtained by the following assumptions for a wire rod laid with a constant tension between two fulcrums, such as a power transmission line and a bridge erection cable. Used in design.
(1) The wire rod is supported by two fulcrums.
(2) A constant load (gravity) acts on the wire rod per unit length.
(3) A constant horizontal tension acts on the wire.
(4) The wire has no bending resistance.

In using the above-mentioned curve in the present invention, the following conditions are premised.
(1) A fulcrum is provided in the vicinity of the top of the pillar 2, and the area between adjacent pillars is the target.
(2) The upper horizontal rope 3 of the pocket type rockfall protection net 1 is the target wire of the above curve.
(3) A constant horizontal tension acts on the upper horizontal rope.
(4) The self-weight of the upper horizontal rope, the vertical rope 51 that hangs down on the upper horizontal rope, the gravity applied to the horizontal rope 52 and the wire net 53 connected to the vertical rope act per unit length of the upper horizontal rope. ..
(5) When there is a horizontal rope suspension rope 42, one end of which is hooked on the fixed portion 16 on the upper slope and the other end is connected to the upper horizontal rope, the rope tension and the unit length act on the rope. The resultant force with the load acts per unit length in the resultant direction.
(6) It is not necessary to consider the bending resistance of the upper horizontal rope except for (4) and (5).
(7) The elastic deformation due to the tensile force acting on the upper horizontal rope does not affect the suspension curve.

Below, regarding the catenary curve, the main symbols used in the present invention are shown below and shown in FIG. 5, and in Formula 1, the force acting per unit length of the wire rod (upper horizontal rope 3) is gravitational fulcrum only. The basic relational expression when the height is the same is shown. It should be noted that cosh and sinh shown in Expression 1 are functions generally called hyperbolic functions, and their definitions and the like are omitted.
(X, y): coordinate system T _h in FIG. 5 (2) in which x is a direction between fulcrums and y is a vertically upward direction: horizontal component of tension on a wire (upper horizontal rope 3) w: unit length of wire Mass (unit horizontal mass of upper horizontal rope and mesh part 53)
g: Gravitational acceleration, w · g (hereinafter, · or × in the mathematical formula represents a product) represents weight.
f: resultant force of “0020” (5) above a: referred to as catenary constant (“Equation 1” (5))
l: Length in the x direction from the lowest point of the wire (upper horizontal rope) to the fulcrum (top of the stanchion 2) (if the fulcrum heights are the same, the length between half fulcrums)
s: curve length of the wire (upper horizontal rope) (S is the curve length when the length in the x direction is 1)
L: Length between fulcrums (length between columns)
h: sag (difference in length in the y direction, which is the height between the lowest point and the highest point of the wire (upper horizontal rope))
R: Reaction force at the fulcrum (top of the column) (force acting upward on the wire)
tan θ: θ is the inclination angle of the curve, tan θ is dy / dx, and θ _l is the inclination angle at the fulcrum

  As shown in FIG. 1, the upper horizontal rope 3 supported by the two columns 2 is suspended between the columns by a horizontal rope suspension rope 42 at a suspension rope connecting portion 33. The connecting parts are connected by a three-way clip 34 as shown in FIG. In addition, regarding the connection of the horizontal rope 52 and the vertical rope 51 in the net portion 5, the four-way clip shown in FIG. 2 is used, and regarding the connection between the horizontal rope and the vertical rope at the end, a three-way clip or a terminal-treated rope is used. With respect to the wire net 53 and the horizontal rope or the vertical rope, a coupling coil (not shown) for connecting the rope and the wire net with a spiral coil is provided. If the specifications of the horizontal rope and the vertical rope are the same, one rope may be used. In this case, the metal fittings installed on the upper horizontal rope must consider the bending due to the change in the installation angle of the hanging rope and the vertical rope (drawing omitted).

  FIG. 4 shows the shape of the upper horizontal rope 3 suspended from the horizontal rope suspension rope 42 from the side direction. As is apparent from the side view of FIG. 4, when there is no horizontal rope suspension rope, the horizontal rope suspension rope can be suspended above the slope with respect to the upper stage horizontal rope suspended in the vertical direction.

  The falling rock 12 generated above the slope enters the opening 13 and the collision energy of the falling rock that collides with the mesh portion 5 is deformed including the collision surface in the mesh portion composed of the wire mesh 53, the vertical rope 51 and the horizontal rope 52. Due to the elastic energy that is applied to the horizontal ropes 52 including the upper horizontal rope 3 that is hooked to the fixed portion due to the collision, and the elastic energy that is applied to the support rope due to the inclination of the support pillar. It absorbs shock. The absorbed energy due to the elastic deformation of the axial force (compressive force) applied to the support columns is negligible compared with the deformation energy of the rope or the like. In contrast to such a conventional pocket type rockfall protection net, in the horizontal rope suspension rope 42 of the present invention, the impact force from the vertical rope and the upper horizontal rope is between the fixed portion above the slope and the horizontal rope suspension rope connecting portion. Part of collision energy of rockfall is absorbed by the energy of elastic deformation and the like. Therefore, the collision energy of the conventional rockfall is further dispersed and absorbed. The horizontal rope suspension rope also has a role of ensuring the opening clearance for suspending the upper horizontal rope above the slope.

  The turnbuckle 43 attached to the horizontal rope suspension rope 42 shown in FIG. 2 is a normal tension adjusting device that changes the positions of both ends by the rotation of the body. By changing the curve length between 33, the tension of the suspension rope can be adjusted. The position of the turnbuckle may be any position on the normal line of the horizontal rope suspension rope.

The vertical force acting on the upper horizontal rope 3 shown in FIG. 3 is a schematic representation of the weight of the upper horizontal rope and the load generated by the net portion 5, and the diagonally upward force is the tension of the horizontal rope suspending rope 42. is there. In this example, as shown in FIG. 3, the tension of the horizontal rope suspension rope is turned so that the direction of the vertical force and the resultant force in the obliquely upward direction are the longitudinal direction of the pillar post 21 and the direction of the foundation. It is adjusted by 43.
If, due to the resultant force, the upper horizontal rope is located in the section D shown in FIG. 4, at the top of the pillar, which is the fulcrum of the upper horizontal rope, the resultant force causes the force to act in the direction indicated by α other than the direction of the pillar base. However, in order to maintain the standing angle of the column 2, the column suspension rope 41 bears the tensile force that opposes this force. This state is affected even when the rockfall 12 collides with the net, and is not desirable in the sense of avoiding the concentration of the impact force and distributing the load as much as possible to try to bear the load.
On the other hand, when the upper horizontal rope is located in the section U shown in FIG. 4, the force acting from the horizontal rope suspension rope to the upper horizontal rope causes the force on the upper part of the pillar to the upper slope of β shown in FIG. It becomes impossible to maintain the standing angle of the column pivotally supported by the portion 15. At the same time, when an impact force is applied, the load on the horizontal rope suspending rope becomes large contrary to the above.
When the direction of the resultant force is the longitudinal direction of the column as in the present invention, all the forces acting from the upper horizontal rope to the column act on the column as compressive force on the column, and the balance state can be maintained by the reaction force from the slope. .. Even when an impact force due to a rock fall is applied, the load of the impact load is distributed in a well-balanced manner on the column suspension rope and the horizontal rope suspension rope.

Table 1 is a basic quantity calculation example for designing a pocket type rockfall protection net according to the invention of claim 3 of the present application. According to the present invention, a case where a vertical force (gravitational force) acts per unit length on the upper horizontal rope 3 in which a constant tension acts in the horizontal direction, based on the basic equation of the catenary curve of Formula 1. The case where the resultant force acts is compared. Regarding the pocket-type rockfall protection net 1 equipped with the upper horizontal rope, the initial tension of the upper horizontal rope is 10,000 N ( The load per unit length in the vertical direction (load on the mesh portion 5) is 0.7 N / mm (about 70 kg weight / m).
In the present embodiment, the case where the resultant force acts is the pocket type rockfall protection net in the invention of claim 2 of the present application. Therefore, the pulling force of the horizontal rope suspension rope 42 is from the direction obliquely upward 45 degrees, and when the magnitude is converted into a unit length, it is w × g × sin (45 °). With respect to the resultant force, its direction is obliquely downward in the longitudinal direction of the column, and the size thereof is f = w × g × cos (45 °) ≈0.71 × w × g.

The sag h, the curve length S, the curve inclination θ _l , and the fulcrum reaction force R in Table 1 have their directions on the suspension surface of the curve, and in the case of Table 1 (2), they are on the vertical plane. A curve and numerical values ((l, h), s) are shown in FIG. 5 (2). The case of Table 1 (3) is an example of numerical calculation on the surface in the direction of resultant force. In the front view (1) and the side view (2) of FIG. 6, the fulcrum length L in Table 1 (2) shows 3.0 m and 12.0 m in solid lines, and the fulcrum length L in Table 1 (3). Is a dotted line showing 12.0 m. When the span length is 12.0 m and only the column suspension rope is used, the upper horizontal rope has a sag h of about 1.3 m from the column top in the vertical direction. This is presumed to be a case where the intermediate support column is lost due to a crash of rockfalls, and the sag h increases further when the weight of the support column acts on the upper horizontal rope. On the other hand, when the horizontal rope suspension rope is provided, in FIG. 6, the horizontal rope suspension rope is provided at three places in the middle of the upper horizontal rope, but in the calculation of Table 1, the unit length is evenly distributed to the upper horizontal rope. It is calculated that the tensile force of the hanging rope acts on the contact surface, and the relaxation h of about 40.0 cm in the resultant direction is observed at 12.0 m. As for the fulcrum reaction force R, the reduction as shown in the table can be confirmed, but it is considered that the lateral rope suspension rope has a high effect of bearing the tension applied to the support column suspension rope from the direction of the force.

  According to claim 4 of the present application, "a pocket type rockfall protection net consisting of a pillar, a pillar suspension rope, an upper stage horizontal rope and a mesh portion according to claim 1" means a conventional pocket without a lateral rope suspension rope 42. Type rockfall protection net, "without changing the load of claim 2 and the clearance of the opening part of claim 1" means that the clearance of the opening part of the conventional pocket type rockfall protection net This is not to change the configuration of the net portion, and is synonymous with not changing the external force setting for the falling rock 12 or the like. "The horizontal pulling force of claim 3 is set to a predetermined value, a new column spacing and column height for expanding the columns are provided, and the horizontal rope suspension rope of claim 1 is provided, and the pocket of claim 1 or 2 is provided. The "type rockfall protection net" is a pocket-type rockfall protection net with a new setting that expands between the columns provided with the horizontal rope suspension rope of the present invention. This is proposed as an alternative construction method of the conventional pocket-type rockfall protection net in the case of disaster restoration work when a pillar is damaged by a rockfall due to a disaster or new construction where the pillar damage due to a rockfall is expected. .. In Example 4 and Example 5, the horizontal tensile force acting on the upper horizontal rope in the pocket type rockfall protection net installed by the conventional type is changed as the predetermined value regarding the horizontal tensile force acting on the upper horizontal rope. Used without. Further, regarding the resultant force, the direction thereof is obliquely downward in the longitudinal direction of the column, and the pocket type rockfall protection net according to claims 2 and 3 is used as an example.

  Table 2 shows an example in which a pillar 2 having a length of 4.0 m is installed on a slope having a slope of 45 degrees in a direction perpendicular to the slope. The conditions such as the falling rock 12 are the same as those of “0028”. The upper horizontal rope erected on the top of the pillar is shown in the bottom row of Table 2 when the length between two fulcrums that do not connect the horizontal rope suspension rope 42 is 3.0 m. This is Condition 2 in Table 2. Based on the opening clearance 14 of about 3.94 m in the condition 2, a horizontal rope suspension rope having a tension so that the resultant force acts in the longitudinal direction of the column without changing the unit length load of the upper horizontal rope is used. An example of calculation of the clearance and the necessary bulkiness height is shown for the inter-post lengths of 6.0 m, 9.0 m, and 12.0 m under the provided condition 1.

6 (1) and 6 (2) show a case in which all the intermediate support columns are lost in the section with a span length of 12.0 m with respect to the arrangement of columns with a span length of 3.0 m, for example. FIG. 7 (1) shows the case where the intermediate support pillar is similarly lost in the sections of 0 m, 9.0 m and 12.0 m.
In such a state, FIG. 7B shows a state in which the columns at both ends sandwiching the lost intermediate column are raised to the same height with respect to the height of the columns for ensuring the clearance of the opening. Table 2 shows an example of numerical calculation when the span length L is 6.0 m to 12.0 m with respect to L = 6.0 m in FIG. 7 (2).
The tan θ in Table 2 is the inclination at the fulcrum shown in Formula 1, and due to the effect of the inclination tan θ, the horizontal pulling force of the upper horizontal rope acts downward at the fulcrum and the force acting on the unit length of the upper horizontal rope causes the strut to rise. The force acting from the top toward the foundation is the fulcrum reaction force R shown in Formula 1. This fulcrum reaction force R needs to be designed as an initial load at the time of facility maintenance by adding a force due to an impact at the time of a rockfall collision to design the column.
Further, in Table 2, the curve length S is calculated. When the same horizontal force as in the conventional type is applied to the upper horizontal rope, it can be an approximate value indicating the required rope extension depending on the expansion of the strut spacing.
As described above, the use of the catenary curve is logical and simple and highly useful for various variations of the upper horizontal rope, the suspension rope, and the columns in the pocket-type rockfall protection net. This is accompanied by uncertain factors such as the effect of elastic deformation, the effect of thermal expansion, and the effect of bending resistance, and it is desirable to use it together with the introduction of a high margin and a safety factor for various settings.

  In the fifth embodiment, as shown in FIG. 7C, only one side is raised. The conditions are the same as in Example 4. Table 3 shows a calculation example corresponding to a fulcrum length L of 3.0 m to 12.0 m. The fulcrum length of 3 m shown in the bottom row of Table 3 is the same as that of Table 2, and shows the basic numerical value according to the conventional type. For the distance between fulcrums 6 m to 12 m, as shown in FIG. 7C, an example of calculation is shown in which the fulcrum of one fulcrum is raised without changing the height of one fulcrum. The fulcrum length is 6.0 m, and the other fulcrum needs to be raised by 447.5 mm. Further, when the lengths between the fulcrums are 9 m and 12 m, the heights of the raised points are 1352.4 mm and 2734.8 mm, respectively, and thus a large raised amount is required as compared with the first embodiment.

Claims 3 and 5 of the present application are based on the assumption that the shape drawn by the upper horizontal rope 3 installed on the column is approximated by a catenary curve, and Example 3 is a specific example of Claim 3. It shows a part of the design example, and also shows a design example by the method of claim 5. In addition, Example 4 and Example 5 are examples of the invention according to Claim 4 in which the pocket type rockfall protection net of Claim 3 is exemplified and the method of Claim 5 is used.
The catenary curve whose basic formula is shown in Formula 1 can theoretically be expanded by the Maclaurin series shown in Formula 2 (1), and for example, parabolic approximation can be performed by the quadratic approximation shown in Formula 2 (2). .. The present invention is also included in the invention based on the catenary curve regarding the calculation of the sag h, the elongation S, the height of the raised pad, etc. by the approximate expression of the catenary curve.

1 pocket type rockfall protection net, 11 rocks or slopes, 12 rockfalls, 13 openings, 14 clearances, 15 foundations, 16 fixed parts,
2 columns, 21 columns, 22 columns top, 23 upper horizontal rope connection, 24 suspension rope connections (column)
3 Upper horizontal rope, 31 Upper horizontal rope fixing part, 32 Vertical rope connecting part, 33 Hanging rope connecting part (rope), 34 3 way clip, 35 Rope terminal treatment 4 Hanging rope, 41 Strut hanging rope, 42 Horizontal rope hanging rope , 43 turnbuckle 5 mesh part, 51 vertical rope, 52 horizontal rope, 53 wire mesh, 54 4 way clip

Claims (5)

A pocket-type rockfall protection net,
A plurality of columns that are axially supported by the foundation provided on the slope and stand upright,
A column suspension rope that has one end hooked to a fixed portion on the upper slope of the ground on which the column is installed and the other end connected at the upper portion of the column, and that suspends the standing state of the column. ,
Both ends are hooked to different fixing parts, and an upper stage horizontal rope installed between the plurality of struts in the middle part,
A plurality of vertical ropes hanging from the opening formed between the upper horizontal rope and the slope and hanging from the upper horizontal rope, a plurality of horizontal ropes connected to the plurality of vertical ropes, and a plurality of the horizontal ropes. A mesh portion including a wire mesh stretched on a horizontal rope or a vertical rope of
A horizontal rope suspension rope having one end hooked to a fixed portion of the upper slope of the ground where the upper horizontal rope is installed and the other end connected to suspend the upper horizontal rope,
Pocket type rockfall protection net with. The pocket-type rockfall protection net according to claim 1,
Pocket type with the tension of the horizontal rope hanging rope set so that the direction of the resultant force between the load generated on the upper horizontal rope due to the weight of the upper horizontal rope and the weight of the net and the tension of the horizontal rope hanging rope is the longitudinal direction of the column. Rockfall protection net. The pocket-type rockfall protection net according to claim 1 or 2,
The load of claim 2 or the resultant force of claim 2 is converted per unit length of the upper horizontal rope, and calculated from the force acting per unit length of the upper horizontal rope and the horizontal tensile force acting on the upper horizontal rope. As a curve drawn between the fulcrums between the fulcrums in the vertical direction of the upper horizontal rope between the struts or in the direction in which the resultant force acts, pocket type rockfall protection used in the design of the stanchion, upper horizontal rope or horizontal rope suspension rope network.   With respect to the pocket type rockfall protection net consisting of the prop, the prop suspension rope, the upper horizontal rope, and the net portion according to claim 1, the load according to claim 2 and the horizontal clearance according to claim 3 are maintained without changing the clearance of the opening. The pocket-type rockfall protection net according to claim 1 or 2, which has a lateral column suspension rope and a new column height for expanding the space between the columns with the directional tensile force being a predetermined value, and is provided with the horizontal rope suspension rope of claim 1. A method of designing a pocket-type rockfall protection net according to claim 1 or claim 2,
Calculating or setting the force acting per unit length of the resultant force according to claim 3;
Calculating or setting the horizontal tensile force of claim 3;
Calculating a catenary curve from the force acting per unit length and the horizontal tensile force,
A method of designing a pillar interval, a pillar height, or a pillar structure between pillars provided with.

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