阅读说明：本技术 一种膨胀土坡生态保护用的土层锚固结构及使用方法 (Soil layer anchoring structure for ecological protection of expansive soil slope and using method ) 是由 王妹丽 李瑞瑞 刘亚配 闫凯莉 其他发明人请求不公开姓名 于 2020-09-15 设计创作，主要内容包括：一种膨胀土坡生态保护用的土层锚固结构及使用方法,锚固结构设置在膨胀土坡的坡面上事先挖好的锥形孔内,包括对称设置的两个弧形锚固基体和两根固定锚固杆,两个弧形锚固基体之间形成种植根系发达植物的种植腔,两侧边缘之间不接触形成受力缓冲区；两根固定锚固杆呈交叉分布,每根固定锚固杆的上端穿出一个弧形锚固基体,下端依次穿过种植腔和另一个弧形锚固基体后插入到锥形孔侧壁的泥土内。本发明通过在膨胀土坡面上挖设锥形孔,并在每个锥形孔内设置锚固结构,锚固结构能够将锥形孔附近的土体进行锚固和改良,形成锚固节点,防止出现浅层滑坡,在锚固结构内种植根系发达的植物,利用其根系来防止水土流失。(A soil layer anchoring structure for ecological protection of an expansive soil slope and a use method thereof are disclosed, wherein the anchoring structure is arranged in a conical hole dug in advance on the slope surface of the expansive soil slope and comprises two arc anchoring matrixes and two fixed anchoring rods which are symmetrically arranged, a planting cavity for planting plants with developed root systems is formed between the two arc anchoring matrixes, and the edges of two sides are not contacted to form a stress buffer area; two fixed anchor rods are distributed in a cross mode, the upper end of each fixed anchor rod penetrates out of an arc-shaped anchor matrix, and the lower end of each fixed anchor rod penetrates through the planting cavity and the other arc-shaped anchor matrix in sequence and then is inserted into soil on the side wall of the conical hole. According to the invention, the conical holes are dug on the expansive soil slope surface, the anchoring structure is arranged in each conical hole, the anchoring structure can anchor and improve the soil body near the conical hole to form an anchoring node to prevent shallow landslide, plants with developed root systems are planted in the anchoring structure, and the root systems are utilized to prevent water and soil loss.)

1. The utility model provides a soil layer anchor structure that inflation soil slope ecological protection used, this anchor structure sets up in the conical hole dug in advance on the domatic of inflation soil slope, its characterized in that: the plant root system fixing device comprises two arc-shaped anchoring substrates (1) and two fixing anchoring rods (5) which are symmetrically arranged, wherein the two arc-shaped anchoring substrates (1) are positioned on the same conical contour, so that a planting cavity (2) for planting plants with developed root systems is formed between the two arc-shaped anchoring substrates, and holes (102) for the plant root systems to penetrate through are distributed on the surfaces of the two arc-shaped anchoring substrates (1); the two side edges of the two arc-shaped anchoring base bodies (1) are not contacted with each other, so that two stress buffer areas (3) are formed, arc-shaped supporting pieces (4) are distributed on the two side edges of each arc-shaped anchoring base body (1) along the length direction of the generatrix, a gap is formed between the two adjacent supporting pieces (4) on the same side, the supporting pieces (4) on the two arc-shaped anchoring base bodies (1) are staggered with each other, so that the arc-shaped anchoring base bodies are inserted into the gap, and a gap is also formed between the end part of the supporting piece (4) on one arc-shaped anchoring base body (1) and the side edge of the other arc-shaped; two fixed anchor pole (5) be the crisscross distribution, an arc anchor base member (1) is worn out to the upper end of every fixed anchor pole (5), the lower extreme passes in proper order and inserts in the earth of bell mouth lateral wall behind planting chamber (2) and another arc anchor base member (1).

2. The soil anchoring structure for ecological protection of the expansive soil slope as recited in claim 1, wherein: the support sheets (4) on the two arc-shaped anchoring base bodies (1) and the two arc-shaped anchoring base bodies (1) are positioned on the same conical contour.

3. A soil anchoring structure for ecological protection of an expansive soil slope as claimed in claim 1 or 2, wherein: in the conical profile of the two arc-shaped anchoring matrixes (1), the conical vertex angle of the cone is 20-40 degrees; the height of the two arc-shaped anchoring matrixes (1) is 30-80 cm.

4. The soil anchoring structure for ecological protection of the expansive soil slope as recited in claim 1, wherein: each arc-shaped anchoring base body (1) comprises a conical part (101), the conical part (101) is formed by cutting the whole cone along the generatrix direction of the conical part, the horizontal section of the formed conical part (101) is a minor arc, and the central angle of the minor arc is 40-60 degrees.

5. The soil anchoring structure for ecological protection of the expansive soil slope as recited in claim 1, wherein: the inclination angles of the two fixed anchoring rods (5) are 45-70 degrees, the bottom ends of the two fixed anchoring rods exceed the bottom of the arc anchoring base body (1) by at least 5cm, and the length of each fixed anchoring rod (5) inserted into soil on the side wall of the conical hole is not less than 30 cm.

6. The soil anchoring structure for ecological protection of the expansive soil slope as recited in claim 1, wherein: the bottom of the two arc anchoring basal bodies (1) is enclosed into a disconnected round hole, a vertical downward positioning anchoring rod (6) is inserted into the round hole, the top end of the positioning anchoring rod (6) is positioned at the bottom of the planting cavity (2), and the bottom end of the positioning anchoring rod penetrates through the round hole enclosed by the bottom of the two arc anchoring basal bodies (1) and then is wedged into the expansive soil at the bottom of the tapered hole.

7. The soil anchoring structure for ecological protection of the expansive soil slope as recited in claim 1, wherein: the top parts of the two arc-shaped anchoring substrates (1) are provided with arc-shaped extending parts (103), and the arc-shaped extending parts (103) on the two arc-shaped anchoring substrates (1) are positioned on the outline of the same cylinder; the two arc-shaped extending parts (103) exceed the tapered hole, so that after plants are planted in the planting cavity (2), the two arc-shaped extending parts (103) are exposed on a soil layer, the upper ends of the two fixed anchoring rods (5) penetrate through the two arc-shaped extending parts (103), and the lower ends of the two fixed anchoring rods penetrate through the planting cavity (2) and the arc-shaped anchoring base body (1) on the opposite side in sequence and then are inserted into soil on the side wall of the tapered hole.

8. The soil anchoring structure for ecological protection of the expansive soil slope as recited in claim 1, wherein: the two arc-shaped anchoring substrates (1), the supporting sheets (4) on the two arc-shaped anchoring substrates and the fixed anchoring rods (5) are made of slurry formed by mixing sawdust, collapsible loess, coarse sand, cement and water according to the mass ratio of 1:8:4:2:5, the slurry is injected into a mold, and the slurry is naturally condensed.

9. Method for protecting ecology of expansive soil slopes by means of soil anchoring structures as claimed in claim 1, comprising the steps of:

1) digging conical holes on the slope surface of the expansive soil slope at a distance of 1m, and then placing an anchoring structure in each conical hole, wherein the depth of each conical hole is smaller than the height of the arc-shaped anchoring base body (1) in the anchoring structure, so that inclined holes which are arranged at the upper parts of the two arc-shaped anchoring base bodies (1) and are used for fixing the anchoring rods (5) to pass through are exposed outside the conical holes;

2) in a conical hole, two arc-shaped anchoring substrates (1) are respectively arranged in the conical hole according to the arrangement mode of claim 1, and the two arc-shaped anchoring substrates are arranged close to the inner wall of the conical hole from left to right;

3) a fixed anchoring rod (5) penetrates through an inclined hole in the upper part of the left arc-shaped anchoring base body (1), then penetrates out of an inclined hole in the lower part of the right arc-shaped anchoring base body (1), and is wedged into expansive soil on the side wall of the conical hole;

4) according to the method of the step 3), another fixed anchoring rod (5) penetrates through the inclined hole at the upper part of the right arc-shaped anchoring base body (1), then penetrates out of the inclined hole at the lower part of the left arc-shaped anchoring base body (1), and is wedged into the expansive soil on the side wall of the conical hole, so that the two arc-shaped anchoring base bodies (1) are connected into a whole and anchored in the conical hole;

5) building rubbish with the grain diameter not more than 10mm is filled into the planting cavity (2) defined by the two arc anchoring substrates (1), the filling height is 1/5-1/10 of the overall height of the planting cavity (2), so that a building rubbish bottom layer is formed, then loess is paved and planted on the building rubbish bottom layer, and vine-shaped plants which are suitable for growing in the loess and have developed root systems are planted.

10. The method for protecting ecology of an expansive soil slope as recited in claim 9, wherein: the loess planted in the step 5) is formed by mixing collapsible loess, fine-particle building rubbish with the particle size not more than 5mm and medium-particle building rubbish with the particle size of 10-20mm in a mass ratio of 75:15: 10.

Technical Field

The invention relates to the field of ecological environment treatment and protection, in particular to a soil layer anchoring structure for ecological protection of an expansive soil slope and a using method thereof.

Background

The expansive soil has a wide distribution range in China, such as Guangxi, Yunnan, Henan, Hubei, Sichuan, Shanxi, Hebei, Anhui, Jiangsu and the like, and has the characteristics of water absorption expansion, water loss shrinkage, repeated expansion and shrinkage deformation, water immersion bearing capacity attenuation, dry shrinkage crack development and the like.

In hilly areas with less precipitation in China, such as the western and southern areas of the Henan, the total precipitation all the year round is less, and most of the precipitation is concentrated in summer and autumn, gentle slope vegetation formed by expansive soil bodies is fragile, and is washed by rainstorm suddenly, so that water and soil loss is easy to occur, even shallow landslides of surface soil are caused, and finally, the ecological vegetation of the expansive soil slopes is completely damaged.

Disclosure of Invention

The invention provides a soil layer anchoring structure for ecological protection of an expansive soil slope and a use method thereof, aiming at solving the problems of water and soil loss, even ecological damage such as shallow landslide and the like caused by the fact that the expansive soil slope with less vegetation is washed by heavy rain in rainy seasons.

The technical scheme adopted by the invention for solving the technical problems is as follows: a soil layer anchoring structure for ecological protection of an expansive soil slope is arranged in a conical hole dug in advance on the slope surface of the expansive soil slope and comprises two arc-shaped anchoring matrixes and two fixed anchoring rods which are symmetrically arranged, wherein the two arc-shaped anchoring matrixes are positioned on the same conical contour, so that a planting cavity for planting plants with developed root systems is formed between the two arc-shaped anchoring matrixes, and holes for the plant root systems to penetrate through are distributed on the surfaces of the two arc-shaped anchoring matrixes; the two side edges of the two arc-shaped anchoring matrixes are not contacted with each other, so that two stress buffer areas are formed, arc-shaped supporting pieces are distributed on the two side edges of each arc-shaped anchoring matrix along the length direction of the generatrix of the arc-shaped anchoring matrix, a gap is formed between the two adjacent supporting pieces on the same side, the supporting pieces on the two arc-shaped anchoring matrixes are staggered with each other so as to be inserted into the gap between the supporting pieces, and a gap is formed between the end part of the supporting piece on one arc-shaped anchoring matrix and the side edge of the other arc-shaped anchoring; the two fixed anchoring rods are distributed in a cross mode, the upper end of each fixed anchoring rod penetrates out of one arc anchoring base body, and the lower end of each fixed anchoring rod penetrates through the planting cavity and the other arc anchoring base body in sequence and then is inserted into soil on the side wall of the conical hole. The upper part and the lower part of each arc anchoring base body are respectively provided with an inclined hole for the fixed anchoring rod to pass through, one fixed anchoring rod firstly passes through the inclined hole on the upper part of one arc anchoring base body and enters the planting cavity, and then continuously passes through the inclined hole on the lower part of the other arc anchoring base body and then is inserted into soil on the side wall of the tapered hole, so that the two arc anchoring base bodies and the side wall of the tapered hole form an integrated structure.

In a preferred embodiment of the present invention, the support pieces on the two arc-shaped anchoring substrates and the two arc-shaped anchoring substrates are on the same conical contour.

In another preferred embodiment of the present invention, in the conical profile where the two arc-shaped anchoring substrates are located, the cone vertex angle of the cone is 20 to 40 °; the height of the two arc-shaped anchoring matrixes is 30-80 cm.

In another preferred embodiment of the present invention, each of the arc-shaped anchoring bases includes a conical portion formed by cutting the entire cone in a direction of a generatrix thereof, and a horizontal cross section of the formed conical portion is a minor arc having a central angle of 40 to 60 °.

In another preferred embodiment of the invention, the two fixing and anchoring rods are inclined at an angle of 45-70 degrees, the bottom ends of the two fixing and anchoring rods exceed the bottom of the arc-shaped anchoring base by at least 5cm, and the length of each fixing and anchoring rod inserted into soil on the side wall of the conical hole is not less than 30 cm.

In another preferred embodiment of the present invention, the bottom of the two arc-shaped anchoring substrates define a broken circular hole, and a positioning anchoring rod which is vertically downward is inserted into the circular hole, the top end of the positioning anchoring rod is located at the bottom of the planting cavity, and the bottom end of the positioning anchoring rod penetrates through the circular hole defined by the bottom of the two arc-shaped anchoring substrates and is then wedged into the expansive soil at the bottom of the conical hole.

In another preferred embodiment of the present invention, the top of the two arc-shaped anchoring bases has an arc-shaped extension, and the arc-shaped extensions on the two arc-shaped anchoring bases are located on the contour of the same cylinder; two arc extensions surpass the bell mouth to after planting the intracavity and planting the plant, two arc extensions expose on the soil layer, two arc extensions are passed respectively to the upper end of two fixed anchor poles, and the lower extreme passes in proper order and plants the chamber and insert in the earth of bell mouth lateral wall behind the arc anchor base member of offside.

In another preferred embodiment of the invention, the two arc-shaped anchoring substrates, the supporting sheets thereon and the fixed anchoring rods are made of sawdust, collapsible loess, coarse sand, cement and water which are mixed in a mass ratio of 1:8:4:2:5 to form slurry, the slurry is injected into a mold and naturally coagulated to form the anchor; the coarse sand adopts a nonuniform coefficient Cu which is d60/d10 and is more than or equal to 3.36.

The method for preventing the water and soil loss of the expansive soil slope surface by utilizing the anchoring structure comprises the following steps:

1) digging conical holes on the expansive soil slope surface at a distance of 1m, and then placing an anchoring structure in each conical hole, wherein the depth of each conical hole is smaller than the height of an arc anchoring base body in each anchoring structure, so that inclined holes which are arranged at the upper parts of the two arc anchoring base bodies and used for fixing anchoring rods to penetrate through are exposed outside the conical holes;

2) in a conical hole, two arc anchoring substrates are respectively arranged in the conical hole according to the arrangement mode, and one of the two arc anchoring substrates is arranged close to the inner wall of the conical hole from left to right;

3) a fixed anchoring rod penetrates through an inclined hole in the upper part of the left arc-shaped anchoring base body, then penetrates out of an inclined hole in the lower part of the right arc-shaped anchoring base body, and is wedged into expansive soil on the side wall of the conical hole;

4) according to the method of the step 3), another fixed anchoring rod penetrates through the inclined hole at the upper part of the right arc-shaped anchoring base body, then penetrates out of the inclined hole at the lower part of the left arc-shaped anchoring base body, and is wedged into the expansive soil on the side wall of the conical hole, so that the two arc-shaped anchoring base bodies are connected into a whole and anchored in the conical hole;

5) building rubbish with the grain diameter not more than 10mm is filled into a planting cavity defined by the two arc anchoring substrates, the filling height is 1/5-1/10 of the overall height of the planting cavity, so that a building rubbish bottom layer is formed, then loess is paved and planted on the building rubbish bottom layer, and vine-shaped plants which are suitable for growing in the loess and have developed root systems are planted.

In another preferred embodiment of the present invention, the loess planted in the step 5) is formed by mixing collapsible loess, fine granular construction waste having a grain size of not more than 5mm and medium granular construction waste having a grain size of 10-20mm in a mass ratio of 75:15: 10.

The construction waste used in the invention adopts crushed waste masonry and waste concrete.

Compared with the prior art, the invention has the following beneficial effects:

according to the invention, the conical holes are dug on the expansive soil slope surface, the anchoring structure is arranged in each conical hole, the anchoring structure can anchor and improve the soil body near the conical hole to form an anchoring node to prevent shallow landslide, plants with developed root systems are planted in the anchoring structure, and the root systems are utilized to prevent water and soil loss, so that the effect of protecting the ecological environment and the system of the expansive soil slope is achieved;

in the anchoring structure, a stress buffer area is formed between two arc anchoring substrates, and a plurality of arc supporting sheets are staggered with each other, so that when the anchoring structure and the conical holes of the expansive soil slope surface are integrated, the anchoring structure can play a role of anchoring nodes, the overall mechanical property of an expansive soil layer is enhanced, and the generation of shallow landslides is reduced to the greatest extent; the two fixed anchoring rods can penetrate into the ground to deeply anchor a soil layer in a certain area around the conical hole besides connecting the anchoring structure and the expansive soil slope into a whole; the existence of the positioning anchoring rod can further strengthen the anchoring effect on deep soil; the arc anchoring base body is provided with an arc extension part exposed on the ground, and the part exposed on the ground can play a certain role in blocking and storing water;

the arc anchoring base body, the supporting sheet and the fixed anchoring rod are formed by selecting sawdust, collapsible loess, coarse sand, cement and water for grouting and then condensing, and because the collapsible loess has the characteristics of uniform soil quality, loose structure and pore development, when the collapsible loess is not soaked by water, the intensity is generally higher, the compressibility is smaller, and the expansive soil has the characteristics of violent expansion in volume after soaking and obviously contracted cohesive soil in volume after water loss; the invention utilizes collapsible loess, coarse sand, cement and water to mix and slip the slurry and form the anchor structure with certain strength to support, when receiving the rainwater to wash, utilize skeleton action of coarse sand to produce the seepage flow channel in the anchor structure, will soak and permeate the loess to the swelling soil continuously effectively, utilize the collapsible characteristic of the loess to mitigate the swelling soil effectively, to solve and expand the defect easy to be taken away by the rainwater after being easy to wash;

4) when the vine-shaped plants are planted in the anchoring structure, the building garbage particles with the particle size not more than 10mm are filled at the bottom, so that an isolation layer is formed, the root system of the plants can be expanded to the periphery as much as possible to anchor expansive soil with a larger area, and a better water storage effect can be achieved; then, planting loess formed by loess, fine particle building rubbish and medium particle building rubbish is laid on the isolation layer, wherein the loess is required for plant growth and mainly provides a continuous loess source for the anchoring structure, and the loess can be continuously poured into the expansive soil through a seepage channel in the anchoring structure along with rainwater scouring; the fine-particle building waste and the medium-particle building waste can increase the porosity of the loess, so that rainwater can be conveniently infiltrated, absorbed and accumulated;

5) the construction waste used in the invention has uneven distribution of broken particle size and more complex components, when the construction waste is mixed with expansive soil, the expansive soil can reduce uneven gradation of the construction waste, and the strong water absorbability and alkalinity of the construction waste particles reduce the water sensitivity of the expansive soil, thereby improving the expansive soil and reducing the quantity of the expansive soil taken away by rainwater washing.

Drawings

FIG. 1 is a schematic view of the overall structure of the anchoring structure of the present invention;

FIG. 2 is a cross-sectional view of FIG. 1;

reference numerals: 1. the device comprises an arc anchoring base body, 101, a conical part, 102, a hole, 103, an arc extending part, 2, a planting cavity, 3, a stress buffer area, 4, a supporting sheet, 5, a fixed anchoring rod and 6, and a positioning anchoring rod.

Detailed Description

The technical solution of the present invention is further described with reference to the following specific embodiments.

Example 1

As shown in fig. 1 and 2, a soil layer anchoring structure for ecological protection of an expansive soil slope is arranged in a conical hole dug in advance on the slope surface of the expansive soil slope, and comprises two arc-shaped anchoring matrixes 1 and two fixed anchoring rods 5 which are symmetrically arranged, wherein the two arc-shaped anchoring matrixes 1 are positioned on the same conical contour, so that a planting cavity 2 for planting plants with developed root systems is formed between the two arc-shaped anchoring matrixes 1, and holes 102 for the plant root systems to pass through are distributed on the surfaces of the two arc-shaped anchoring matrixes 1; the two side edges of the two arc-shaped anchoring base bodies 1 are not contacted with each other, so that two stress buffer areas 3 are formed, arc-shaped supporting pieces 4 are distributed on the two side edges of each arc-shaped anchoring base body 1 along the length direction of the generatrix, a gap is formed between two adjacent supporting pieces 4 on the same side, the supporting pieces 4 on the two arc-shaped anchoring base bodies 1 are staggered with each other, so that the supporting pieces are inserted into the gap, and a gap is formed between the end part of the supporting piece 4 on one arc-shaped anchoring base body 1 and the side edge of the other arc-shaped anchoring base body 1; two fixed anchor rods 5 be the crisscross distribution, an arc anchoring base member 1 is worn out to the upper end of every fixed anchor rod 5, the lower extreme passes in proper order and inserts in the earth of bell mouth lateral wall behind planting chamber 2 and another arc anchoring base member 1.

In this embodiment, the upper portion and the lower portion of each arc anchoring base 1 are provided with an inclined hole for the fixed anchoring rod 5 to pass through, and one fixed anchoring rod 5 firstly passes through the inclined hole on the upper portion of one arc anchoring base 1 and enters the planting cavity 2, and then continuously passes through the inclined hole on the lower portion of the other arc anchoring base 1 and then is inserted into soil on the side wall of the tapered hole, so that the two arc anchoring bases 1 and the side wall of the tapered hole form an integrated structure.

The method for preventing the water and soil loss of the expansive soil slope surface by utilizing the anchoring structure comprises the following steps:

1) digging conical holes on the expansive soil slope surface at a distance of 1m, and then placing an anchoring structure in each conical hole, wherein the depth of each conical hole is smaller than the height of the arc-shaped anchoring base body 1 in each anchoring structure, so that inclined holes for the fixed anchoring rods 5 to pass through are arranged at the upper parts of the two arc-shaped anchoring base bodies 1 and are exposed outside the conical holes;

2) in a conical hole, two arc-shaped anchoring matrixes 1 are respectively arranged in the conical hole according to the arrangement mode, and one of the two arc-shaped anchoring matrixes is arranged close to the inner wall of the conical hole;

3) a fixed anchoring rod 5 penetrates through an inclined hole in the upper part of the left arc-shaped anchoring base body 1, then penetrates out of an inclined hole in the lower part of the right arc-shaped anchoring base body 1, and is wedged into expansive soil on the side wall of the conical hole;

4) according to the method of the step 3), another fixed anchoring rod 5 penetrates through the inclined hole at the upper part of the right arc-shaped anchoring base 1, then penetrates out of the inclined hole at the lower part of the left arc-shaped anchoring base 1, and is wedged into the expansive soil on the side wall of the conical hole, so that the two arc-shaped anchoring bases 1 are connected into a whole and anchored in the conical hole;

5) building rubbish with the grain diameter not more than 10mm is filled into a planting cavity 2 defined by the two arc anchoring matrixes 1, the filling height is 1/5-1/10 of the overall height of the planting cavity 2, so that a building rubbish bottom layer is formed, then loess is paved and planted on the building rubbish bottom layer, and vine-shaped plants which are suitable for growing in the loess and have developed root systems are planted; when planting, watering and fertilizing are needed;

6) and (3) completing the installation of the anchoring structure in one conical hole, then installing and fixing each conical hole anchoring structure according to the method, and transplanting the vine-shaped plants.

The foregoing is a basic embodiment of the present invention, and further modifications, optimizations and limitations can be made on the foregoing, so as to obtain the following examples:

example 2

This embodiment is an improved scheme based on embodiment 1, and the main structure thereof is the same as embodiment 1, and the improvement point is that: the support sheets 4 on the two arc-shaped anchoring substrates 1 and the two arc-shaped anchoring substrates 1 are positioned on the same conical contour.

Example 3

The present embodiment is another modified scheme based on embodiment 1, and the main structure of the present embodiment is the same as that of embodiment 1, and the improvement point is that: in the conical profile of the two arc-shaped anchoring matrixes 1, the conical vertex angle of the cone is 20-40 degrees; the height of the two arc-shaped anchoring matrixes 1 is 30-80 cm.

Of course, this embodiment may also be improved on the basis of embodiment 2, and the improvement contents are consistent.

Example 4

The present embodiment is another modified scheme based on embodiment 1, and the main structure of the present embodiment is the same as that of embodiment 1, and the improvement point is that: each of the arc-shaped anchoring matrixes 1 comprises a conical part 101, the conical part 101 is formed by cutting the whole cone along the generatrix direction of the cone, the horizontal section of the formed conical part 101 is a minor arc, and the central angle of the minor arc is 40-60 degrees.

Example 5

The present embodiment is another modified scheme based on embodiment 1, and the main structure of the present embodiment is the same as that of embodiment 1, and the improvement point is that: the inclination angles of the two fixed anchoring rods 5 are 45-70 degrees, the bottom ends of the two fixed anchoring rods exceed the bottom of the arc anchoring matrix 1 by at least 5cm, and the length of each fixed anchoring rod 5 inserted into soil on the side wall of the conical hole is not less than 30 cm.

Example 6

The present embodiment is another modified scheme based on embodiment 1, and the main structure of the present embodiment is the same as that of embodiment 1, and the improvement point is that: the bottom of the two arc anchoring basal bodies 1 is enclosed to form a disconnected round hole, a vertical downward positioning anchoring rod 6 is inserted into the round hole, the top end of the positioning anchoring rod 6 is positioned at the bottom of the planting cavity 2, the bottom end of the positioning anchoring rod penetrates through the round hole enclosed by the bottom of the two arc anchoring basal bodies 1 and then is wedged into expansive soil at the bottom of the tapered hole, and the wedging length is generally 30-60 cm.

This embodiment is used the same as embodiment 1 except that after step 4), the positioning anchor rods 6 are inserted into the ground, and then the filling of the construction waste particles and the planting of loess in step 5) are performed.

Example 7

The present embodiment is another modified scheme based on embodiment 1, and the main structure of the present embodiment is the same as that of embodiment 1, and the improvement point is that: the top parts of the two arc-shaped anchoring matrixes 1 are provided with arc-shaped extending parts 103, and the arc-shaped extending parts 103 on the two arc-shaped anchoring matrixes 1 are positioned on the outline of the same cylinder; the two arc-shaped extending parts 103 exceed the tapered hole, so that after the plants are planted in the planting cavity 2, the two arc-shaped extending parts 103 are exposed on the soil layer, the upper ends of the two fixing and anchoring rods 5 respectively penetrate through the two arc-shaped extending parts 103, the lower ends of the two fixing and anchoring rods sequentially penetrate through the planting cavity 2 and the arc-shaped anchoring base body 1 on the opposite side and then are inserted into soil on the side wall of the tapered hole, and the height of the arc-shaped extending parts 103 is generally 3-10 cm.

Example 8

The present embodiment is another modified scheme based on embodiment 1, and the main structure of the present embodiment is the same as that of embodiment 1, and the improvement point is that: the two arc-shaped anchoring substrates 1, the supporting sheets 4 on the two arc-shaped anchoring substrates and the fixed anchoring rods 5 are made of slurry formed by mixing sawdust, collapsible loess, coarse sand, cement and water according to the mass ratio of 1:8:4:2:5, the slurry is injected into a mold, and the slurry is naturally condensed.

In the embodiment, the coarse sand is coarse sand with the nonuniform coefficient Cu of d60/d10 of more than or equal to 3.36.

Example 9

The present embodiment is another modified scheme based on embodiment 1, and the main structure of the present embodiment is the same as that of embodiment 1, and the improvement point is that: the loess planted in the step 5) is formed by mixing collapsible loess, fine-particle building rubbish with the particle size not more than 5mm and medium-particle building rubbish with the particle size of 10-20mm in a mass ratio of 75:15: 10.