JPH0723036U - Slope protection block - Google Patents

Abstract

(57) [Abstract] [Purpose] The present invention relates to a slope protection block, which is arranged vertically and horizontally on the slope to prevent collapse of the slope from erosion in the natural environment such as sun and rain, and during laying work. The purpose is to enable quick positioning, transportation and handling of the block body, improve the efficiency, and prevent the block body from slipping and cracking the joint material due to vibration and use over time. [Structure] The concrete block main body 1 is provided with locking means 2 for connecting male and female in the vertical direction, and locking means 3 for connecting the male and female in the horizontal direction is provided on the left and right sides to obtain a slope N. The block main bodies are arranged vertically and horizontally on the front surface of the above to lock the locking means 2, 2; 3, 3 adjacent to each other.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention is used to protect the slopes from collapse and collapse from erosion in the natural environment such as the sun, rainwater, running water, snow, frost, etc. by arranging them vertically and horizontally on the slopes beside roads and on river banks. The block for slope protection used.

[0002]

[Prior art]

 Conventionally, a slope protection block for protecting slopes near roads and riverbanks from the erosion of the sun, rainwater, running water, snow, frost, etc. is shown in Fig. 12 for example. There was one shown in 14. That is, there was a panel main body a having a substantially rectangular front face formed by pouring concrete into a mold, then curing and solidifying the concrete. The size of the panel main body a is such that the vertical and horizontal dimensions can be carried by hand, and for example, the vertical dimension 1 and the horizontal dimension 1'are each formed of several tens of cm. In use, the panel body a is manually arranged to be arranged vertically and horizontally on the surface of the slope N having the inclination θ. Then, the joint material m such as cement mortar or adhesive is filled in the space between the adjacent panel main bodies a that are arranged on the surface of the slope N in the vertical direction X and the horizontal direction Y to cover the slope N. By doing so, the panel bodies a were stacked vertically and horizontally, and the laying work was performed.

[0003]

[Problems to be solved by the device]

 However, in the conventional slope protection block shown in FIGS. 12 to 14, the adjacent block bodies a arranged vertically and horizontally are abutted against each other and the joint material m is filled between the abutting surfaces of the block bodies a. Since the block main bodies a are fixed to each other by the above so as to cover the slope N 1, it takes time and labor to carry and handle the block main bodies a during the laying work, and the mutual positioning work of the block main bodies a, which results in work efficiency. Was bad. Moreover, since the binding force of the joint material m will decrease with running water on the road, vibration such as an earthquake, or running water during river flooding, etc. The block bodies a, which were stacked on the front surface of the surface N and arranged in the vertical and horizontal directions, were displaced relative to each other, and gaps and cracks were generated at the installation location of the joint material m. Rainwater invades from the gaps and cracks to erode the slope N, and sunlight is incident to promote the growth of weeds, which has been a cause of accelerating the collapse of the slope N.

The present invention enables quick and reliable positioning, transportation, and handling of the block main body during laying work, improves work efficiency, and adds vibrations due to earthquakes, etc., or against running water during flooding of rivers or It is an object of the present invention to provide a slope protection block that is structurally robust by preventing the block main body from shifting due to use over time and by preventing gaps from being formed in joints and the like.

[0005]

[Means for Solving the Problems]

 The present invention has been made in view of the above problems.A block body formed of concrete in a substantially plate shape is used as a slope protection block that covers the slope vertically and horizontally, and a male and female block is provided above and below the block body. Locking means for connecting in the vertical direction is provided, and the locking means for male and female is provided so that the corresponding block bodies arranged in the vertical direction can be locked to each other, and the male and female locking means are provided on the left and right of the block body. A locking means for connecting in the left-right direction is provided, and the male and female locking means is provided so that the corresponding block main bodies arranged in the left-right direction can be locked with each other.

[0006]

[Action]

 Vertically connecting male locking means provided at the top and bottom of the block body are fitted into female locking means provided at corresponding locations in the vertically adjacent block body to perform vertical positioning, and Positioning in the left-right direction by inserting the male locking means for connecting in the left-right direction on the left and right sides of the block body into the female locking means provided at the corresponding location in the adjacent block body in the left-right direction. By laying construction.

[0007]

【Example】

 An embodiment of the present invention will be described below with reference to FIGS. Reference numeral 1 is a substantially plate-shaped block body having a substantially rectangular front surface and a pseudo-stone pattern on the entire surface. The block body 1 is formed by placing concrete in a formwork, then curing and solidifying. The block main body 1 is provided with locking means 2 for connecting male and female in the vertical direction on the upper and lower sides thereof, and locking means 3 for connecting the male and female in the horizontal direction on the left and right of the block body 1.

Of these, the locking means 2 for connecting in the vertical direction is provided on the upper front surface of the block body 1 with two locking recesses 4 and 4 having a substantially U-shaped cross section and on the lower rear surface of the block body 1. It is formed of two locking convex portions 5 and 5 each having a substantially U-shaped cross section. The adjacent block main bodies 1 arranged in the vertical direction, that is, the corresponding locking projections 5 and 5 of the block main body 1 located above are fitted into the locking recesses 4 and 4 of the block main body 1 in a lockable manner. It

The size (depth) t ₁ of the locking recess 4 reaches approximately the middle of the block body 1, and the installation length of the locking projection 5, that is, the size t ′ from the front surface of the block body 1. Similarly, ₁ is formed so as to reach approximately the middle of the block body 1, so that the block body 1 is particularly positioned in the vertical direction (direction intersecting the longitudinal direction) X to prevent rattling and displacement. In addition, the positioning and rattling in the left-right direction (longitudinal direction of the block body 1) Y and in the thickness direction (direction intersecting the longitudinal direction) Z are prevented. Moreover, the locking recesses 4 and 4 are formed inwardly from the left and right side ends of the block body 1 with a length of about 385 mm starting from a position of about 120 mm, for example. The locking projections 5 and 5 are formed inward from the left and right side ends of the block body 1 with a length of about 185 mm starting from a position of about 220 mm, for example.

Further, the locking means 3 for connecting in the left-right direction is formed with a locking recess 6 and a locking projection 7 which are substantially trapezoidal in plan view on the left and right front surfaces of the block body 1 in a symmetrical manner. The locking recesses 6 and 6 provided symmetrically on the left and right side surfaces of the block body 1 correspond to the corresponding locking projections 7 of the front and rear block bodies 1 and 1 arranged in the left-right direction. 7 is fitted so as to be able to be locked, particularly in the left-right direction (longitudinal direction of the block body 1) Y, and in the vertical direction (direction intersecting with the longitudinal direction) X, and further in the thickness direction (direction intersecting with the longitudinal direction). ) Position the Z block body 1 at the installation position and prevent displacement and rattling.

The dimension t ₂ of the locking recess 6 in the thickness direction of the block body 1 is approximately in the middle of the block body 1. The dimension t _'2 in the thickness direction of the locking portion 7 is formed to likewise lead to a substantially middle of the block body 1. As shown in FIG. 1, the size of the block main body 1 in this embodiment is about 800 mm in the vertical dimension, 1250 mm in the horizontal dimension, and about 370 mm in the thickness. The block body 1 weighs about 750 kg.

As shown in FIGS. 9 and 10, 8 is a tie band having a substantially rectangular front shape, and the tie band 8 collides the abutting ends S, S of the block bodies 1, 1 arranged in the left-right direction Y. After joining, the block bodies 1 and 1 are firmly connected in the left-right direction Y by being installed between the abutting ends S and S and screwing the bolts 9 and 9 into the inserts 9a and 9a.

Reference numeral 10 denotes two groove portions provided on the back surface of the block body 1, and the fork portion 11 a of the lifting tool 11 is detachably inserted into the groove portions 10 and 10 and lifted to lift the block body 1. Transport or move (see Fig. 11). Reference numeral 12 is an insert for fixing the block body 1 to the hanger 11 when the hanger 11 of the block body 1 is hoisted, and bolts 12a and 12a are screwed into the insert 12 to suspend the hanger 11. The block body 1 is fixed to the tool 11.

The hanger 11 has a fork part 11a for inserting the hook 11 into the groove part 10 on one side and a hook 14 attached to the tip of the tow line 13 on the other side for balancing during hoisting. There are several holes 11b ₁ , 11b ₂ , 11b ₃ that are removably inserted in the hole.

Reference numeral 15 denotes a packing attached to the block body 1 at a substantially middle peripheral edge in the thickness direction Z. The packing 15 is arranged vertically and horizontally on the front surface of the slope N as shown in FIG. In this case, by maintaining the watertightness of the block main bodies 1 adjacent to each other in the vertical and horizontal directions, back pressure such as sediment and water pressure is applied to the back surface of the block main body 1 to prevent the outflow of sediment from the slope N. In order to prevent the backfilling material 17 packed in the back of the slope N from being sucked out and caused by the flow of the river when the slope N of the river is covered with the block body 1. belongs to.

Reference numeral 16 is a foundation portion for supporting the lowermost block body 1 arranged in a horizontal row, and the foundation portion 16 is formed by using concrete or the like on the upper surface of a crushed stone (not shown). . Reference numeral 17 denotes a back of crushed stone, crushed stone, etc. packed in a gap K formed between the slope N and the back surface of the block body 1 which is arranged in the vertical and horizontal directions along the slope θ in front of the slope N. It is an included material.

One embodiment of the present invention is configured as described above, and in order to perform construction to cover the slope N of a road, riverbank, etc., first, concrete is used on the upper surface of the stones not shown in the figure. To form the base portion 16.

By arranging the block bodies 1 on the upper surface of the base portion 16 in the left-right direction Y with respect to the surface of the slope N, the block bodies 1 at the lowermost stage are sequentially arranged in a horizontal row.

In order to arrange the block main bodies 1 in a horizontal row, first of all, the locking concave portions 6 and 6 and the locking convex portions 7 and 7 of the substantially trapezoidal plane which are symmetrically provided on the left and right front surfaces of the block main body The locking projections 7 of the adjacent succeeding block bodies 1 are fitted into the locking recesses 6, and the locking projections 7 are fitted into the locking recesses 6 of the following succeeding block bodies 1. At this time, the locking projections 7 of the succeeding block body 1 are fitted into the locking recesses 6 of the preceding block body 1, and the locking projections 7 of the preceding block body 1 are fitted in the succeeding block body 1. By fitting in the locking recess 6, it is possible to easily position the block main bodies 1 relative to each other, particularly in the left-right direction (longitudinal direction of the block main body 1) Y, and also in the vertical direction (of the block main body 1 The block main body 1 is positioned in the horizontal direction in a row, and the thickness direction of the block main body 1 (the direction crossing the block main body 1 in the longitudinal direction) Z is determined. .

Since one of the conventional block bodies occupies an area for laying the block body, and two groove portions 10, 10 are formed on the back surface of the block body 1 having a weight of 750 kg, By inserting the fork portion 11a of the lifting tool 11 into the groove portions 10 and lifting the block body 1 by the lifting tool 11 as shown in FIG. 11, the block body 1 can be easily transported to a desired location. Since it can be moved, work efficiency is improved.

Thereafter, a tie band 8 is installed between the abutting ends S 1, S 2 of the adjacent block bodies 1 arranged in a horizontal row in the left-right direction, and the bolts 9, 9 are screwed into the inserts 9a, 9a. Thus, the block main bodies 1 and 1 adjacent to each other in the left-right direction Y are connected to each other.

Next, similarly, the second-stage block body 1 is sequentially stacked on the bottom-stage block body 1, but the second-stage block body 1 is staggered with respect to the lowest-stage block body 1. Stack in a shape.

To this end, one of the two locking recesses 4 and 4 (for example, the right side) for vertically connecting provided on the upper front surface of the lowermost block main body 1 (for example, on the right side) is provided with By inserting one (for example, the left side) locking projection 5 of the two locking projections 5 and 5 provided on the lower rear surface of the second stage block body 1 to be placed on the upper surface The block body at the bottom is stacked on the upper surface of the block body 1 at the second stage. The other (right side) locking projection 5 of the second-stage block body 1 is fitted into one (left side) locking recess 4 of the block body 1 subsequent to the bottommost block body 1. Thus, the block main bodies 1 are arranged in a staggered manner in a horizontal row, and the block main bodies 1 adjacent to each other in the vertical direction X 1 are positioned and arranged. In this manner, as shown in FIGS. 7 and 8, a desired number of block main bodies 1 are stacked in a staggered pattern in the vertical and horizontal directions along the slope θ of the slope N in front of the slope N.

At this time, the locking recesses 4 and 4 are formed inward from the left and right side edges of the upper front surface of the block body 1 with a length of about 385 mm starting from a position of about 120 mm, for example. The engaging projections 5 and 5 of the other adjacent block main bodies 1 which are fitted in the stopper recesses 4 and 4 and which are arranged in the upper direction are inward from the left and right starting ends of the lower rear surface of the block main body 1 by, for example, about 220 mm. Since it is formed smaller than the locking recesses 4 and 4 with a length of about 185 mm starting from the position, the locking projections 5 and 5 of the upper block body 1 in the locking recesses 4 and 4 are left and right. You can move in any direction. Therefore, the block body 1 of the second stage arranged above the block body 1 of the lowest stage can be moved in the left-right direction Y to adjust the mounting position according to the situation at the site. Further, the locking recesses 4 and 4 are substantially U-shaped in cross section, and the locking projections 5 and 5 which are fitted into the locking recesses 4 and 4 are substantially U-shaped in cross section. The mounting angle between the block main bodies 1 and 1 arranged in the vertical direction is adjusted in the thickness direction Z in accordance with the degree of inclination of the steep slope N 1 and the depth of the undulations formed on the surface of the slope N. You can

After that, the joint material 18 is filled in the gap P provided between the adjacent ones of the block main bodies arranged vertically and horizontally and vertically adjacent to each other.

Further, the backing material 17 such as crushed stone or crushed stone is packed in the gap K between the slope N and the back surface of the block main body 1 vertically and horizontally stacked in front of the slope N to perform the laying construction work. Complete.

In this way, the slope N is covered by the block body 1 being arranged vertically and horizontally, so that when the vehicle runs on the road or when vibration is applied due to an earthquake, The locking means 2 for connecting the male and female provided in the vertical direction, that is, provided in the lower rear surface of the block main body 1 vertically adjacent to each other in the locking concave portion 4 provided in the upper front surface of the block main body 1 By fitting the locking convex portion 5, in particular, rattling and slipping movement in the up and down directions X are prevented, and rattling and slipping movement in the thickness direction Z 1 of the block body 1 are also prevented. In addition, the locking means 3 for connecting in the left-right direction provided on the left and right side surfaces of the block body 1, that is, the locking projections 7, 7 symmetrically provided on the left and right sides of the block body 1, the locking projections on the opposite side. By fitting the portions 7 into the locking recesses 6 of the adjacent block bodies 1, rattling in the horizontal direction Y is particularly prevented, and rattling and slipping movement in the vertical direction X and the thickness direction Z are also prevented. It Therefore, the joint material 18 filled between the vertically and horizontally adjacent block main bodies 1 is prevented from cracking to prevent sunlight from entering and weeds to grow, or rainwater or snow from entering the cracked portion to cut the slope. N is prevented from collapsing or collapsing. Moreover, since the packing 15 is attached to the block body 1 at the substantially middle edge thereof, when the block body 1 is vertically and horizontally arranged on the front surface of the slope N as shown in FIGS. By maintaining the watertightness of the block main bodies 1 to each other, back pressure such as sediment and water pressure is applied from the back surface of the block main body 1 to prevent the sediment from flowing out of the slope N and also to the slope N of the river. When the block body 1 is covered with the block body 1, the backing material 17 packed in the back surface of the slope N can be prevented from being sucked out due to the flow of the river.

In the above embodiment, the shape of the block body 1 is formed in a substantially rectangular shape on the front surface, but this is an example, and other shapes may be formed, for example, a square shape on the front surface. Moreover, the number of installations of the locking projections 5 and the locking recesses 4 of the locking means 2 for the vertical coupling and the number of the locking projections 7 and the locking concaves 6 of the locking means 3 for the horizontal coupling are increased or decreased. Are free.

[0029]

[Effect of device]

 As described above, the present invention enables quick and reliable positioning, transportation and handling of the block body during laying work, improves work efficiency, and adds vibration, or when the block body is used when a river is flooded or is used over time. It is possible to prevent the gap from moving and to prevent the formation of cracks or other gaps in the places where the jointing material is installed, thus making the structure robust.

[Brief description of drawings]

FIG. 1 is a front view showing an embodiment of the present invention.

FIG. 2 is a plan view of the same.

FIG. 3 is a bottom view of the same.

FIG. 4 is a rear view of the same.

FIG. 5 is a right side view of the same.

6 is a sectional view taken along the line AA of FIG.

FIG. 7 is a front view showing a laid state in which the slope surface is covered.

FIG. 8 is a vertical cross-sectional view showing a state of being laid on a slope as well.

FIG. 9 is an enlarged front view showing a connected state between adjacent block main bodies.

FIG. 10 is an enlarged partial sectional view showing a connected state of the same.

FIG. 11 is a side view showing a state in which the block main body is hoisted and carried by a hoisting tool.

FIG. 12 is a perspective view showing a conventional slope protection block of this type.

FIG. 13 is a front view showing a state of being laid on a slope as well.

FIG. 14 is a sectional view showing a laid state of the same.

[Explanation of symbols]

1 block body 2 locking means 3 engaging device 4 engagement recess 5 locking projection 6 engaging recesses 7 locking projections 8 tie band 9 bolt 10 groove 11 suspender 11a fork N slopes t ₁ dimension t ' ₁ dimension t ₂ dimension t ′ ₂ dimension

Claims (6)

[Scope of utility model registration request] 1. A slope protection block for vertically and horizontally covering a slope by a block body made of concrete and having a substantially plate shape, and locking means for vertically connecting male and female is provided above and below the block body. , The male and female locking means are provided so that the corresponding block bodies arranged vertically can be locked with each other, and locking means for connecting the male and female left and right directions are provided on the left and right of the block body. The slope protection block, wherein the female locking means is provided so that the corresponding block bodies arranged in the left-right direction can be locked to each other. 2. The block main body arranged in the left-right direction,
The slope protection block according to claim 1, wherein the abutting ends of the block body are bolted and connected to each other through a tie band. 3. The locking means for connecting in the vertical direction comprises a convex portion having a substantially middle size of the block main body, and a concave portion provided at a corresponding portion into which the convex portion can be fitted. The slope protection block according to claim 1. 4. The locking means for connecting in the left-right direction has a convex portion having a substantially middle size of the block main body and a concave portion into which the convex portion can be fitted, symmetrically on the left and right side surfaces of the block main body. The slope protection block according to claim 1, wherein the block is provided on the slope. 5. The slope protection block according to claim 1, wherein packing is attached to a peripheral edge of the block body. 6. The slope protection block according to claim 1, wherein a groove portion is provided on the back surface of the block body so that the fork portion of the hanging tool can be inserted and removed.