JP2005023760A - Soil protection mat and its construction method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a soil protection mat enabling various construction corresponding to purpose and place of construction by changing direction of construction. <P>SOLUTION: A block upper part 21 positioned on an upper face side of a sheet 30 is formed by a shape having at least one set of a side face α where an inclination angle formed for a sheet face is θ degree and a side face β where an inclination angle formed for the sheet face is ϕ degree which is smaller than θ degree. The side face α in one block upper part 21 and the side face β in the other block upper part 21 adjacent to one block upper part 21 form a pair to form a channel 40 between mutual block upper parts. Consequently, sunlight does not reach a bottom part 41 of the channel to prevent deterioration of the sheet 30 and prevent weed from growing from the channel 40. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a soil protection mat that is laid and constructed on a soil surface. In particular, it relates to a soil protection mat (slope protection mat) to be constructed on the slope. Moreover, it is related with the construction method of a soil protection mat.

  A plurality of blocks 24 as shown in FIG. 14 are connected and supported by mesh-like sheets 30 embedded in the blocks 24 as soil protection mats used in river and lake revetment works and floor protection works. A soil protection mat 12 is conventionally known. Since the soil protection mat 12 is flexible at the boundary between the blocks, as shown in FIG. 15, it is suspended by a lifting tool 70 or laid along the soil surface. Is possible.

  For example, in Japanese Patent Application Laid-Open No. 11-117314 (Patent Document 1), there is a block span for soil protection composed of a connecting material made of resin fiber or steel and a plurality of concrete blocks, and the connecting material is made of each concrete. A soil protection block span is described in which the concrete blocks adjacent to each other are connected to each other by the connecting material while being sandwiched in layers inside the block. Thus, it is described that flexibility can be imparted to the soil protection block span, and that the connecting material can exert a bar arrangement effect. It also describes that the concrete block can be prevented from peeling from the connecting material.

JP-A-11-117314 (Claims, Effects of the Invention, FIGS. 1 and 2)

  However, the soil protection block span described in Patent Document 1 is such that the joint portion is widely opened upward, and therefore when the connecting material is made of resin fiber, the joint portion between the concrete blocks is connected. There is a risk that the material will deteriorate due to exposure to sunlight over a long period of time during the day. Moreover, when a connection material consists of steel materials, there exists a possibility that rust may arise by rain. When the connecting material deteriorates and breaks, it is dangerous because not only the soil flows out from the portion but also the soil surface may collapse. In either case, weeds cannot be effectively prevented from growing from the joints of the blocks. Furthermore, since all the side surfaces of the concrete block are inclined at the same inclination angle with respect to the connecting material, even if the laying direction is changed, only a uniform effect can be obtained.

  This invention is made | formed in order to solve the said subject, and it aims at providing the soil protection mat which a sheet | seat does not deteriorate easily. It is also an object of the present invention to provide a soil protection mat on which weeds are less likely to grow. Furthermore, it is also an object of the present invention to provide a soil protection mat capable of various constructions by changing the laying direction. Furthermore, it is also an object of the present invention to provide a method for constructing a soil protection mat that can be suitably used on various soil surfaces.

  In the soil protection mat in which a plurality of blocks are connected and supported by a mesh-like sheet embedded in the block, the upper part of the block located on the upper surface side of the sheet is on the sheet surface. It has a shape having at least one set of a side surface α having an inclination angle of θ degrees and a side surface β having an inclination angle of φ degrees smaller than θ degrees with respect to the seat surface. And a soil protection mat characterized in that a groove is formed between the upper portions of the blocks, and a side surface β of the upper portion of the other block adjacent to the upper portion of the one block is paired. The Thus, by making the upper part of the block asymmetrical, the direction of the soil protection mat can be appropriately selected according to the place and purpose of laying. In addition, depending on the values of the inclination angle θ and the inclination angle φ, it is possible to effectively prevent the deterioration of the sheet and the weeds from the groove by shading the bottom of the groove between the upper blocks. Become.

  At this time, it is preferable that θ is larger than 90 degrees. Thereby, it becomes easy to form a shade at the bottom of the groove between the upper portions of the blocks, and it becomes possible to prevent deterioration of the sheet due to ultraviolet rays. θ is more preferably 100 degrees or more, and further preferably 110 degrees or more. It is optimal that the angle is 115 degrees or more. However, if θ is too large, the upper portion of the block is likely to be broken by an external force. Therefore, θ is preferably 150 degrees or less. θ is more preferably 140 degrees or less, and further preferably 130 degrees or less. It is optimal to be 125 degrees or less.

  Moreover, it is preferable that φ is 20 degrees or more. When φ is smaller than 20 degrees, the upper part of the block is easily broken by an external force. φ is more preferably 30 ° or more, and further preferably 35 ° or more. It is optimal to be 40 degrees or more. However, if φ is too large, the flexibility of the soil protection mat may be insufficient. Therefore, φ is preferably 80 degrees or less. φ is more preferably 65 ° or less, and further preferably 55 ° or less. It is optimal to be 50 degrees or less.

  Furthermore, the difference between θ and φ is preferably 5 degrees or more. This makes it possible to incline the grooves between the upper portions of the blocks and make it difficult for sunlight to reach the bottom. The difference between θ and φ is more preferably 30 degrees or more, and further preferably 50 degrees or more. It is optimal that the angle is 60 degrees or more. However, if the difference between θ and φ is too large, the upper portion of the block is likely to be broken by an external force. Therefore, the difference between θ and φ is preferably 140 degrees or less. The difference between θ and φ is more preferably 120 degrees or less, and further preferably 100 degrees or less. It is optimal to be 90 degrees or less.

  Furthermore, it is also preferable that the sum of θ and φ is 120 degrees or more. If the sum of θ and φ is less than 120 degrees, the bottom of the groove between the block tops may be exposed to sunlight for a long time during the day. The sum of θ and φ is more preferably 140 degrees or more, and further preferably 155 degrees or more. It is optimal that the angle is 160 degrees or more. However, if the sum of θ and φ is too large, not only the flexibility of the soil protection mat will be insufficient, but it may be difficult to remove the block, so the sum of θ and φ is 180 degrees. The following is preferable. The sum of θ and φ is more preferably 175 degrees or less, and further preferably 170 degrees or less.

  In the upper part of the block, it is also preferable that the side surface α side and the side surface β side have different thicknesses. Thereby, the action of the soil protection mat can be greatly different depending on the direction of laying, and the soil protection mat can be provided with various functions. For example, when a soil protection mat is applied to a slope, a step can be formed at the upper part of the block. It is preferable to form the side surface α side thicker than the side surface β side because it is possible to form a shade in a wider range near the bottom of the groove between the block upper portions.

  The shape of the portion where the block covers the sheet is not particularly limited as long as it is a shape that can be spread, such as a triangle or a quadrangle, but is preferably a parallelogram. Thereby, not only can the shape of the block be unified, but also the direction in which the block is arranged can be unified in one direction, so that the soil protection mat can be easily manufactured and constructed. The shape of the portion where the block covers the sheet is more preferably a rectangle or rhombus, and more preferably a square.

  At this time, it is preferable that the upper portion of the block has a shape having two sides α and β. Thereby, it is also possible to make all the bottoms of the grooves between the block upper parts shade. At this time, it is more preferable that the side surfaces α are arranged adjacent to each other. As a result, it is possible to simultaneously perform die cutting of a plurality of block upper portions with one mold frame.

  Further, in the soil protection mat in which a plurality of blocks are connected and supported by being fixed to the upper surface of the sheet, the block has an inclination angle formed with respect to the bottom surface fixed to the upper surface of the sheet. It has a shape having at least one set of a side surface α ′ of θ ′ degrees and a side surface β ′ of φ ′ degrees whose inclination angle with respect to the bottom surface is smaller than θ ′ degrees, and the side surface α ′ of one block, The problem can also be solved by providing a soil protection mat characterized in that a side surface β ′ of another block adjacent to the one block is paired to form a groove between the blocks. This is because the block constituting the soil protection mat is substantially the same as the block upper part constituting the soil protection mat. In this soil protection mat, the inclination angle θ ′, the inclination angle φ ′, the side surface α ′, and the side surface β ′ respectively correspond to the inclination angle θ, the inclination angle φ, the side surface α, and the side surface β in the soil protection mat. .

  Furthermore, the said subject is also solved by providing the construction method of the soil protection mat which lays | lays said soil protection mat on a slope. Thereby, it becomes possible to protect the slope with the possibility of erosion and collapse over a long period of time with a strong soil protection mat.

  Since the soil protection mat of the present invention has a slanted groove between the upper parts of the blocks or between the blocks, it is possible to perform various constructions according to the purpose and place of construction by changing the direction of laying. Is. In addition, since the sunlight hardly reaches the sheet for connecting and supporting the blocks, the sheet is hardly deteriorated and the stability of the construction surface can be improved. It is also possible to prevent weeds from growing on the construction surface. For this reason, it becomes possible to reduce the maintenance cost etc. after construction.

  Hereinafter, the soil protection mat of the present invention will be described in more detail with reference to the drawings. FIG. 1 is a perspective view of a buried type soil protection mat. FIG. 2 is a plan view of a buried type soil protection mat. FIG. 3 is a bottom view of a buried type soil protection mat. FIG. 4 is a front view of a buried type soil protection mat. FIG. 5 is a right side view of a buried type soil protection mat. FIG. 6 is a perspective view of the upper portion of the block. FIG. 7 is an enlarged view of portion A in FIG. FIG. 8 is a right side view showing another embodiment of the soil protection mat of the present invention. FIG. 9 is a view showing a state in which the soil protection mat shown in FIG. 8 is laid on the slope.

  As a preferred embodiment, the soil protection mat of the present invention has a structure in which a plurality of blocks are connected and supported by a mesh sheet embedded in the block (embedded type), and the plurality of blocks are fixed to the upper surface of the sheet. There is a thing (attachment type) which is connected and supported by being done. In the following description, the embedding type soil protection mat will be mainly described. However, the configuration mentioned therein cannot be employed in the sticking type soil protection mat. Unless it is self-evident from the gist, it can also be adopted in an adhesive type soil protection mat.

  As shown in FIGS. 1 to 5, the buried type soil protection mat 10 includes a plurality of blocks 20 connected and supported by a mesh sheet 30 embedded in the blocks. The number of blocks 20 connected and supported by one sheet 30 is appropriately adjusted according to the width of the soil surface to be constructed and the dimensions of the blocks 20, and is not particularly limited, but in the present embodiment, 25 blocks 20 are divided into 5 blocks. Arranged in 5 columns. In the buried type soil protection mat 10, a set of one block upper portion 21 and one block lower portion 22 is called a block 20. At this time, it is preferable that a margin is given to the peripheral edge portion of the sheet 30. Thereby, it becomes possible to ensure the overlap with the adjacent soil protection mat 10, and the part hold | maintained with a hanging tool in the case of construction.

  In this soil protection mat 10, a block upper part 21 located on the upper surface side of the sheet 30 and a block lower part 22 located on the lower surface side of the sheet 30 are integrally formed via a mesh-like sheet 30. Therefore, the fixing strength between the block 20 and the sheet 30 is excellent. Moreover, since the block lower part 22 plays the role of an anchor, it is excellent also in installation stability, and is suitably used even when the soil surface to be laid has a complicated shape or a steep slope. It is something that can be done.

  As shown in FIG. 6, the block upper portion 21 is formed into a shape having one upper surface 50 and four side surfaces (52 to 55). FIG. 6 shows only the block upper part 21 for the convenience of explanation. In actuality, the sheet 30 and the block lower part 22 exist below the virtual bottom surface 51. The virtual bottom surface 51 coincides with a portion where the block 20 covers the sheet 30 and is parallel to the sheet surface. Both the upper surface 50 and the virtual bottom surface 51 are square. The upper surface 50 may be provided with a design. The length of one side of the virtual bottom surface 51 is usually 50 to 500 mm, and is 200 mm in this embodiment. Moreover, the thickness of the block upper part 21 is 5-50 mm normally, and is 20 mm in this embodiment.

  Further, the two adjacent side surfaces (52, 53) are side surfaces α having an inclination angle θ of 120 degrees with respect to the seat surface, and the remaining two side surfaces (54, 55) are formed with respect to the seat surface. The tilt angle φ to be formed is the side surface β of 45 degrees. As shown in FIG. 7, one block upper side surface α is paired with another block upper side surface β adjacent to the one block upper portion to form a groove 40 between the block upper portions. In the figure, the lower end of the side surface α and the lower end of the side surface β are in contact with each other at the bottom 41 of the groove, but this is schematically shown. In practice, the lower end of the side surface α and the lower end of the side surface β There is a case where a gap is formed between the sheets 30 and the sheet 30 is viewed through the gap. Further, when it is desired to hit an anchor pin between the upper portions of the blocks, a gap may be intentionally provided. The difference between θ and φ is 75 degrees in the present embodiment, and the inclination angle of the groove 40 (the angle formed by the plane that bisects the angle formed by the side surface α and the side surface β with respect to the sheet surface). It is 52.5 degrees (= 90− (θ−φ) / 2). Further, the sum of θ and φ is 165 degrees, and the opening angle of the groove 40 (angle formed by the side surface α and the side surface β) is 15 degrees (= 180− (θ + φ)).

  The shape of the upper part of the block is not limited to the above, and the upper surface and the virtual bottom surface may be triangular or hexagonal. Examples of such a shape include a triangular prism and a hexagonal prism (including a plate having a low height). Moreover, the shape which does not have an upper surface may be sufficient as a block upper part. As such a shape, for example, a pentahedron in which the virtual bottom surface is a quadrangle, one of the pair of side surfaces connected to each side of the virtual bottom surface is a triangle, and the other pair of side surfaces is a square. Illustrated.

  Moreover, the upper surface 50 and the virtual bottom surface 51 of the block upper part 21 of this embodiment are parallel, and the thickness of the side surface α side is equal to the thickness of the side surface β side, but the soil protection shown in FIG. A material having a different thickness L1 on the side surface α side and a thickness L2 on the side surface β side, such as the mat 11, is also suitable. The block upper portion 23 of the soil protection mat 11 has a thickness L1 on the side surface α side that is thicker than a thickness L2 on the side surface β side. As a result, as shown in FIG. 9, it is possible to form steps on the slope 60 with the upper surface of the block upper portion 23 being stepped. Further, when the soil protection mat 11 is laid in the direction opposite to the direction of FIG. 9 (so that the side surface α faces upward of the slope of the slope), a cue can be formed on the slope 60. For this reason, the soil protection mat 11 is suitable for use in revetments for lakes and rivers where people gather. As a result, a person who falls into the water can easily climb up to the land.

  As shown in FIGS. 3 to 5, the block lower portion 22 is formed into a quadrangular pyramid shape in consideration of the flexibility of the soil protection mat 10 and the installation stability on the laying surface. The thickness of the block lower part 22 and the shape of the bottom surface are determined in consideration of the hardness and inclination of the soil surface on which the soil protection mat 10 is laid. The thickness of the block lower part 22 is usually 5 to 50 mm, and is 20 mm in this embodiment. The bottom surface of the block lower part 22 is a square having a side length of 180 mm. The virtual upper surface of the block lower portion 22 is a square having a side length of 200 mm and coincides with the virtual bottom surface 51 of the block upper portion 21.

  The raw material of the block 20 should just have sufficient durability to protect soil, and can illustrate concrete and mortar. In this embodiment, concrete is used. Moreover, depending on the place and purpose of constructing the soil protection mat 10, mortar or resin mixed with wood chips, ash, carbide, etc. may be used, or these materials may be molded porous. . The block 20 is usually formed by pouring a material into a mold.

  When the sheet 30 is used for a sticking type soil protection mat, a densely woven fabric may be used, but in this embodiment of the buried type, the block upper part 21 and the block lower part 22 In consideration of the connection and water permeability, mesh fabric is used. The material of the sheet 30 may be any material having sufficient strength to protect the soil, and examples thereof include fiber materials such as vinylon and nylon, and flat yarn materials such as polypropylene and polyethylene. The sheet 30 is manufactured by weaving using such a material. It is also preferable to apply a resin coating to the surface of the sheet 30 for the purpose of shielding ultraviolet rays. The dimensions of the sheet 30 are 1600 mm in length and 1300 mm in width in this embodiment.

  Adhesion of the block 20 and the sheet 30 is usually performed using an adhesive if it is an adhesive type soil protection mat, but in the case of an embedded type soil protection mat, it is preferably performed by the following method. . First, a raw material is poured into the lower mold, and a mesh-like sheet 30 is put on it. Next, the upper mold is placed on the sheet 30, the material is poured into the sheet 30, and then the material is solidified. Upside down may be reversed. As a result, the material inside the upper mold and the material inside the lower mold can be solidified in a state where they are connected through the mesh provided in the sheet 30, and the unity between the block 20 and the sheet 30 can be improved. It becomes.

  At this time, when the material flows into the boundary portion between the blocks and solidifies, the adjacent blocks may be solidified in an integrated manner, but this is the flexibility of the soil protection mat 10. It does not have a big influence on. This is because the material solidified at the boundary portion has a thickness that can be naturally cracked when the soil protection mat 10 is suspended by a lifting tool or laid on the soil surface. The crack becomes a joint part viewed by the sheet 30. The width of the joint portion (the width of the bottom portion 41 of the groove) is usually 5 to 20 mm. This joint portion is also used as a place where an anchor pin for fixing the soil protection mat 10 to the soil surface is driven.

  In the above fixing method, the upper mold and the lower mold are molded with a biodegradable plastic typified by an aliphatic polyester such as polylactic acid, and used as a covering material for joints while being embedded in the soil protection mat 10. It is also preferable. Thereby, not only the manufacturing process of the soil protection mat 10 can be simplified, but also the deterioration of the sheet 30 can be further prevented.

  Then, the construction method of the soil protection mat of this invention is demonstrated concretely. The soil protection mat of the present invention can adjust the type and magnitude of the effect obtained by changing the direction in which it is laid. In the following, this will be described using two construction examples, but the construction method of the soil protection mat of the present invention is not limited to this, and the soil protection mat is laid in other directions. It may be. Moreover, although it demonstrates using the buried type soil protection mat 10 shown in FIG. 1, the soil protection mat of another aspect may be used. Further, the soil surface on which the soil protection mat 10 is laid is a south-facing slope (an inclination angle of 30 degrees) located at 35 degrees north latitude, but other soil surfaces can also be used.

First, a first construction example will be described. FIG. 10 shows a state in which the soil protection mat 10 is laid on a south-facing slope 61 (tilt angle 30 degrees) located at 35 degrees north latitude so that the side surface α faces the slope below the slope 61. FIG. The lower block portion 22 is not shown because it is submerged in the soil. Anchor pins are driven into the joints of the soil protection mat 10. The number of anchor pins to be driven varies depending on the weight of the soil protection mat 10 and the inclination angle of the slope, but when a soil protection mat having an area density of 125 to 140 kg / m ² is laid on a slope having an inclination angle of 30 degrees It is preferable to drive 0.6 or more per 1 m ² . Thereby, the soil protection mat 10 can be more strongly fixed to the slope. When the soil protection mat 10 is constructed in such a direction, the groove 40 faces downward of the slope of the slope 61. For this reason, it is suitable when it is desired to prevent dirt and dust from accumulating in the groove 40.

  FIG. 11 is an enlarged view of the portion B in FIG. 10, and when viewed, the sunlight irradiated from the sun at an altitude of 15 degrees (arrow 82) to 30 degrees (arrow 83) is the bottom of the groove. Although it reaches 41, it can be seen that sunlight irradiated from the other high altitude sun cannot reach the bottom 41 of the groove. In particular, it can be seen that sunlight irradiated from the sun at an altitude higher than 30 degrees (arrow 83) cannot reach the bottom 41 of the groove at all. This is convenient for preventing deterioration of the sheet 30. The higher the altitude of the sun it is irradiated with, the shorter the distance it passes through the ozone layer that absorbs UV light, and the more it reaches the sun, the higher the altitude of the sun it is irradiated to. This is because the lower the is, the lower the amount of ultraviolet rays reaches the ground surface. Depending on the inclination angle and direction of the slope 61, the groove bottom 41 can be shaded in all time zones of the year.

  On the other hand, FIG. 16 is a view corresponding to FIG. 11 showing a state in which the conventional soil protection mat 12 shown in FIG. 14 is laid on a slope 61 similar to FIG. The opening angle of the groove between the blocks of the conventional soil protection mat 12 is set to 15 degrees, which is the same as that of the soil protection mat 10 shown in FIG. Looking at this, sunlight irradiated from the sun at an altitude of 0 degrees (arrow 80) to 52.5 degrees (arrow 84) and an altitude of 67.5 degrees (arrow 85) to 78.5 degrees (arrow 81) Although the sunlight irradiated from the sun of the sun cannot reach the bottom 41 of the groove, the sunlight irradiated from a relatively high altitude sun such as 52.5 degrees (arrow 84) to 67.5 degrees (arrow 85) It can be seen that the bottom 41 is reached. For this reason, deterioration of the sheet 30 is not much prevented. Many conventionally used soil protection mats have a groove opening angle between the blocks larger than 15 degrees, and in this case, the deterioration of the sheet 30 becomes more severe.

  Next, a second construction example will be described. FIG. 12 shows a state in which the soil protection mat 10 is laid on the south-facing slope 61 (inclination angle 30 degrees) located at 35 degrees north latitude so that the side surface α faces upward of the slope of the slope 61. FIG. When the soil protection mat 10 is constructed in such a direction, the groove 40 faces upward of the slope of the slope 61. Therefore, it is suitable for forming a scaffold or a cue on the slope 61.

  FIG. 13 is an enlarged view of part C in FIG. 12, and when viewed, all sunlight emitted from the sun at an altitude of 0 degrees (arrow 80) to 78.5 degrees (arrow 81). However, it can be seen that the bottom 41 of the groove cannot be reached. This means that the bottom 41 of the groove is shaded at all times of the year. This is because, at a point of 35 degrees north latitude, the altitude of the sun does not become higher than 78.5 degrees during the south solstice of the summer solstice. The fact that the bottom 41 of the groove is shaded in all time zones of the year is the same not only when the slope of the slope 61 is 30 degrees but also when it is smaller than 41.5 degrees. The slope angle of the slope for laying the soil protection mat is often 40 degrees or less, and in particular, it is often 25 to 35 degrees. It can be suitably used in all aspects.

  As described above, when the soil protection mat is laid on a slope facing the equator whose inclination angle is smaller than θ−x degrees, it is preferable that the side surface α is laid on the upper side of the slope. Here, the equator direction means southward in the northern hemisphere and northward in the southern hemisphere. Moreover, x means the highest altitude of the sun, and in the northern hemisphere, it means the south-middle altitude of the summer solstice. The value of x can be obtained by subtracting the latitude of the point where the soil protection mat is laid from the value obtained by adding 23.5 degrees of the earth axis to 90 degrees. Thereby, it becomes possible to make the bottom part of a groove | channel the shade in all the time zones of the year.

  The construction method of the soil protection mat of the present invention can be suitably used not only when the soil surface to be constructed is land, but also when it is underwater or at the shore. Specifically, it can be suitably used for revetment work and floor protection work such as rivers, lakes and reservoirs. Moreover, when the soil surface to construct is a slope, it can be used suitably also when the soil surface is horizontal.

It is a perspective view of a buried type soil protection mat. It is a top view of a buried type soil protection mat. It is a bottom view of a buried type soil protection mat. It is a front view of a buried type soil protection mat. It is a right view of a buried type soil protection mat. It is a perspective view of a block upper part. It is the figure which expanded the A section in FIG. It is the right view which showed the other aspect of the soil protection mat of this invention. It is the figure which showed the state which laid the soil protection mat shown in FIG. 8 on the slope. 1 shows a state in which the buried type soil protection mat shown in FIG. 1 is laid on the south-facing slope (inclination angle of 30 degrees) located at 35 degrees north latitude so that the side surface α faces downward of the slope of the slope. FIG. It is the figure which expanded the B section in FIG. 1 shows a state in which the buried type soil protection mat shown in FIG. 1 is laid on the south-facing slope (inclination angle 30 degrees) located at 35 degrees north latitude so that the side surface α faces upward of the slope of the slope. FIG. It is the figure which expanded the C section in FIG. It is a perspective view of the conventional soil protection mat. It is the figure which showed the state which lifted the conventional soil protection mat with the hanger. FIG. 12 is a view corresponding to FIG. 11 showing a state in which a conventional soil protection mat is laid on a south-facing slope (inclination angle of 30 degrees) located at 35 degrees north latitude.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Embedded type soil protection mat 11 Other forms of soil protection mat 12 Conventional soil protection mat 20 Block 21 Block upper part 22 Block lower part 23 Block upper part 24 Block 25 Block upper part 26 Block lower part 30 Sheet 40 Groove 41 Groove bottom part 50 Block Upper surface of upper part 51 Virtual bottom surface of upper part of block 52 Side surface of block upper part (side surface α)
53 Side of block top (side α)
54 Side of block top (side β)
55 Side of block top (side β)
60 Slope 61 Slope facing south at 35 degrees north latitude (30 degrees slope)
70 Lifting device 80 Sunlight irradiated from the sun at an altitude of 0 degrees 81 Sunlight irradiated from the sun at an altitude of 78.5 degrees 82 Sunlight irradiated from the sun at an altitude of 15 degrees 83 Irradiation from the sun at an altitude of 30 degrees Sunlight 84 Sunlight irradiated from the sun at an altitude of 52.5 degrees 85 Sunlight irradiated from the sun at an altitude of 67.5 degrees

Claims (9)

  In the soil protection mat in which a plurality of blocks are connected and supported by a mesh-like sheet embedded in the block, the block upper portion located on the upper surface side of the sheet among the blocks is inclined with respect to the sheet surface It has a shape having at least one set of a side surface α having an angle of θ degrees and a side surface β having an inclination angle of φ degrees smaller than θ degrees with respect to the sheet surface, A soil protection mat, characterized in that a groove is formed between the upper portions of the blocks in pairs with the side surfaces β of the upper portions of the blocks adjacent to the upper portions of the blocks.   The soil protection mat according to claim 1, wherein θ is greater than 90 degrees and 150 degrees or less, and φ is 20 degrees or greater and 80 degrees or less.   The soil protection mat according to claim 1 or 2, wherein a difference between θ and φ is 5 degrees or more and 140 degrees or less.   The soil protection mat according to any one of claims 1 to 3, wherein a sum of θ and φ is not less than 120 degrees and not more than 180 degrees.   The soil protection mat according to any one of claims 1 to 4, wherein the thickness is different between the side surface α side and the side surface β side at the top of the block.   The soil protection mat according to any one of claims 1 to 5, wherein a shape of a portion where the block covers the sheet is a parallelogram.   The soil protection mat according to claim 6, wherein the block upper portion has a shape having two side surfaces α and two side surfaces β.   In the soil protection mat in which a plurality of blocks are connected and supported by being fixed to the upper surface of the sheet, the block is a side surface α having an inclination angle of θ ′ degrees with respect to the bottom surface fixed to the upper surface of the sheet. And at least one pair of side surfaces β ′ having an inclination angle of φ ′ degrees smaller than θ ′ degrees, and adjacent to the one side surface α ′. A soil protection mat, wherein a side surface β ′ of another block is paired and a groove is formed between the blocks.   The construction method of the soil protection mat which lays the soil protection mat in any one of Claims 1-8 on a slope.

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