CN219280753U - Gravity type retaining wall - Google Patents

Abstract

The embodiment of the application discloses a gravity type retaining wall, which comprises a bottom plate and vertical plates, wherein at least two vertical plates can be arranged, one end of each vertical plate is fixedly connected with the bottom plate, the other end of each vertical plate extends towards one side far away from the bottom plate, and the vertical plates are fixedly connected with the bottom plate into a whole, so that the stress performance and the overall strength of the gravity type retaining wall can be improved; meanwhile, the vertical plate extends along a first preset direction, the extending length can be determined according to the extending length of the side slope, and the vertical plate is used for supporting the soil body of the side slope so as to realize the integrity of the side slope support; the two adjacent vertical plates are arranged at intervals along a second preset direction, the first preset direction is perpendicular to the second preset direction, and a containing groove is formed between the two adjacent vertical plates and the bottom plate; the planting soil body for planting plants can be filled in the accommodating groove, the weight of the gravity retaining wall is increased, the supporting stability of the gravity retaining wall to the slope soil body is improved, and the anti-slip performance and the anti-capsizing performance of the gravity retaining wall are further improved.

Description

Gravity type retaining wall

Technical Field

The application relates to the technical field of slope support engineering, in particular to a gravity retaining wall.

Background

The field of geotechnical engineering is often limited to paying attention to the safety of engineering itself, but neglecting the importance of landscape aesthetics. Whether it be a highway retaining wall, municipal retaining wall or landscape retaining wall in a field, its retaining and supporting structure is often visually observable by a person.

In order to improve the aesthetic property of the soil-blocking supporting structure, the soil-blocking supporting structure usually adopts the traditional gravity type retaining wall, cantilever type retaining wall or buttress type retaining wall and other modes which are arranged in a grading and sectioning mode to realize the grading greening of the soil-blocking supporting structure; however, the conventional gravity retaining wall, cantilever retaining wall or buttress retaining wall has poor stability and cannot stably support the slope soil.

Disclosure of Invention

The embodiment of the application provides a gravity type retaining wall, which can improve the supporting stability of a slope soil body.

The application provides a gravity retaining wall, including:

a bottom plate;

the planting device comprises at least two vertical plates, wherein one ends of the vertical plates are fixedly connected with the bottom plate, the vertical plates extend along a first preset direction, two adjacent vertical plates are arranged at intervals along a second preset direction, the first preset direction is perpendicular to the second preset direction, and a containing groove for filling planting soil bodies is formed between the two adjacent vertical plates and the bottom plate.

In some embodiments, a gravity retaining wall comprises:

the buttress is positioned in the accommodating groove between two adjacent vertical plates, and the buttress and the vertical plates are arranged at an included angle; the bottom of the buttress is connected with the bottom plate, and at least one of two opposite sides of the buttress connected with the bottom is connected with the vertical plate.

In some embodiments, the bottom of the buttress is connected to the base plate, and opposite sides of the buttress are respectively connected to two adjacent vertical plates.

In some embodiments, when two opposite sides of the buttress are respectively connected with two adjacent vertical plates, at least two buttresses are arranged between the two adjacent vertical plates, the buttresses divide the accommodating groove into a plurality of planting grooves for filling the planting soil body, and the planting grooves are provided with openings far away from the bottom plate.

In some embodiments, the riser is progressively higher along the second predetermined direction.

In some embodiments, the planting soil body fills the accommodating groove, and the planting soil body at least comprises a planting layer.

In some embodiments, the gravity retaining wall further comprises:

the planting soil body further comprises a reverse filtering layer and a water-resisting layer;

the anti-filtering layer is located the planting layer is kept away from the one side of the notch of holding tank, the water-resisting layer is located the anti-filtering layer is kept away from the one side of planting layer, just the anti-filtering layer is located the water-resisting layer with between the planting layer.

In some embodiments, the vertical plate is provided with a plurality of water draining holes, the water draining holes are distributed in an array or in a dot shape, and the water draining holes are communicated with the reverse filtering layer.

In some embodiments, a plurality of the reverse filtering layers and a plurality of the water-resisting layers can be stacked along a third preset direction between the adjacent vertical plates, and the reverse filtering layers and the water-resisting layers are arranged in a crossing manner along the third preset direction; the first preset direction and the second preset direction are perpendicular to the third preset direction.

In some embodiments, the bottom plate is provided with sedimentation slots, and the sedimentation slots are arranged at intervals along the first preset direction; the gravity retaining wall further comprises a filling material; and the filling material is filled in the settlement joint.

Based on the gravity type retaining wall provided by the application, the gravity type retaining wall comprises a bottom plate and vertical plates, wherein at least two vertical plates can be arranged, one end of each vertical plate is fixedly connected with the bottom plate, and the other end of each vertical plate extends towards one side far away from the bottom plate; the vertical plate and the bottom plate are fixedly connected into a whole, so that the stress performance and the overall strength of the gravity retaining wall can be improved; meanwhile, the vertical plate extends along a first preset direction, the extending length can be determined according to the extending length of the side slope, and the vertical plate is used for supporting the soil body of the side slope so as to realize the integrity of the side slope support; the two adjacent vertical plates are arranged at intervals along a second preset direction, the first preset direction is perpendicular to the second preset direction, and a containing groove is formed between the two adjacent vertical plates and the bottom plate; the planting soil body for planting plants can be filled in the accommodating groove, the weight of the gravity retaining wall is increased, the supporting stability of the gravity retaining wall to the slope soil body is improved, and the anti-slip performance and the anti-capsizing performance of the gravity retaining wall are further improved.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic left-view structure of a gravity-type retaining wall according to an embodiment of the present disclosure;

fig. 2 is a schematic top view of a gravity retaining wall according to an embodiment of the present disclosure;

fig. 3 is a schematic left-view structure of a gravity-type retaining wall (the gravity-type retaining wall includes a planting soil body) according to an embodiment of the present disclosure.

Reference numerals illustrate:

10. a bottom plate; 11. a heel plate; 12. a toenail;

20. a vertical plate; 211. a first water discharge hole; 212. a second water discharge hole; 213. a second water discharge hole; 214. a third water discharge hole; 215. a third water discharge hole; 216. a third water discharge hole;

22. a first riser; 23. a second stage riser; 24. a third riser;

30. a receiving groove; 31. a planting groove; 32. an opening;

40. Buttressing; 41. a first stage buttress; 42. a second stage buttress; 43. a third-stage buttress;

50. planting soil mass; 511. a first planting layer; 512. a second planting layer; 521. a first reverse filtration layer; 522. a second reverse filtration layer; 523. a second reverse filtration layer; 524. a third reverse filtration layer; 525. a third second reverse filtration layer; 526. a third filtration layer; 531. a first water-blocking layer; 532. a second water-resistant layer; 533. a second water-resistant layer; 534. a third water-resistant layer; 535. a third water-resistant layer; 536. a third water-resistant layer; 537. a third, fourth, water-barrier layer;

60. a concrete cushion layer; 70. a side slope soil body; 75. plain soil; 80. geotextile; 90. and (3) foundation.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present application more apparent, the following detailed description of the embodiments of the present application will be given with reference to the accompanying drawings.

When the following description refers to the accompanying drawings, the same numbers in different drawings refer to the same or similar elements, unless otherwise indicated. The implementations described in the following exemplary examples are not representative of all implementations consistent with the present application. Rather, they are merely examples of apparatus and methods consistent with some aspects of the present application as detailed in the accompanying claims.

The field of geotechnical engineering is often limited to paying attention to the safety of engineering itself, but neglecting the importance of landscape aesthetics. Whether it be a highway retaining wall, municipal retaining wall or landscape retaining wall in a field, its retaining and supporting structure is often visually observable by a person.

In order to improve the aesthetic property of the soil-blocking supporting structure, the soil-blocking supporting structure usually adopts the traditional gravity type retaining wall, cantilever type retaining wall or buttress type retaining wall and other modes which are arranged in a grading and sectioning mode to realize the grading greening of the soil-blocking supporting structure; however, the conventional gravity retaining wall, cantilever retaining wall or buttress retaining wall has poor stability and cannot stably support the slope soil. In order to meet the requirements of the retaining and supporting structure for anti-slip performance, anti-overturning performance, bearing capacity and deformation, the material consumption, the size and the reinforcement proportioning of the retaining and supporting structure need to be increased, so that the economic value of the retaining and supporting structure is low.

In order to solve the above-mentioned problems, please refer to fig. 1 to 3, the present application provides a gravity type retaining wall, which may include a bottom plate 10 and vertical plates 20, wherein the vertical plates 20 may be at least provided with two, one end of each vertical plate 20 is fixedly connected with the bottom plate 10, and the other end of each vertical plate 20 extends towards one side (Z direction) far away from the bottom plate 10. Meanwhile, the vertical plate 20 extends along a first preset direction, and the first preset direction can be an X direction and is consistent with the extending direction of the side slope, and is used for corresponding to the side slope so as to support the side slope. The length of the vertical plate 20 extending along the X direction can be determined according to the extending length of the side slope, and the vertical plate 20 is used for supporting the side slope soil body, so that the integrity of supporting the side slope soil body is realized.

The two adjacent vertical plates 20 are arranged at intervals along a second preset direction, the first preset direction is perpendicular to the second preset direction, the second preset direction can be the Y direction, and a containing groove 30 is formed between the two adjacent vertical plates 20 and the bottom plate 10; the accommodation groove 30 can be filled with planting soil 50 for planting plants, so that the weight of the gravity retaining wall is increased, the supporting capacity of the gravity retaining wall to the slope soil 70 is improved, the supporting stability of the gravity retaining wall to the slope soil 70 is improved, and the anti-slip performance and anti-capsizing performance of the gravity retaining wall are improved.

The spacing distance between the two vertical plates 20 along the Y direction can be set according to the side pressure of the slope soil 70 to the gravity type retaining wall, and the larger the side pressure of the slope soil 70 to the gravity type retaining wall is, the larger the spacing distance between the two vertical plates 20 along the Y direction is, and the larger the volume of the accommodating groove 30 is; the accommodating groove 30 can be filled with more planting soil bodies 50, so that the overall weight of the gravity retaining wall is increased, the support stability of the slope soil body is improved, and the anti-slip performance and anti-capsizing performance of the gravity retaining wall are improved. The gravity retaining wall can also adjust the interval distance between the two vertical plates 20 along the Y direction according to the height of the side slope and the soil condition of the side slope soil body, and the gravity retaining wall is not limited in the application and can be arranged according to actual requirements.

Further, the vertical plate 20 may also extend in a direction (Z direction) away from the bottom plate 10, so as to increase the volume of the accommodating groove 30, so that the accommodating groove 30 may be filled with more planting soil 50, thereby improving the overall weight of the gravity retaining wall, further improving the stability of supporting the slope soil, and improving the anti-sliding performance and anti-overturning performance of the gravity retaining wall.

Referring to fig. 1 to 3, the base plate 10 may be placed on a concrete cushion layer 60 (the concrete cushion layer 60 serves as a leveling layer, which serves as a hardening work surface), and the concrete cushion layer 60 is placed on a foundation 90 or foundation treatment soil; the concrete cushion layer 60 can provide a relatively flat and hardened working surface, is convenient for placing and manufacturing the bottom plate 10, and improves the convenience of constructing the gravity retaining wall.

In some embodiments, the bottom plate 10 may also be placed on the foundation 90, and the specific placement of the bottom plate 10 on the foundation 90 or the concrete cushion 60 may be set according to actual requirements, which is not limited in this application.

Referring to fig. 1, the sole plate 10 may include a heel plate 11 and a toe plate 12, and the heel plate 11 and the toe plate 12 may be disposed on a concrete cushion 60 and sequentially disposed along the Y direction. Specifically, taking the vertical plate 20 on the side far away from the side slope soil body 70 as an example, the soil facing side (the side close to the side slope soil body 70) is the heel plate 11, the soil backing side (the side far away from the side slope soil body 70) is the toe plate 12, and the weight of the side slope soil body 70 and the planting soil body 50 in the accommodating groove 30 is applied to the heel plate 11, so that the supporting stability of the gravity type retaining wall is improved, that is, the anti-sliding performance and the anti-overturning performance of the gravity type retaining wall can be improved; meanwhile, as the length of the heel plate 11 is increased, the anti-overturning performance of the gravity retaining wall can be effectively improved.

Taking the vertical plate 20 on the side close to the side slope soil body 70 as an example, the soil facing side (the side close to the side slope soil body 70) is the heel plate 11, the soil backing side (the side far away from the side slope soil body 70) is the toe plate 12, and the weight of the side slope soil body 70 is applied to the heel plate 11, so that the supporting stability of the gravity type retaining wall is improved, that is, the anti-slip performance and the anti-overturning performance of the gravity type retaining wall are improved.

It should be noted that, the bottom plate 10 may be divided into a vertical plate 20, the portion of the bottom plate 10 located on the soil facing side is a heel plate 11, and the portion of the bottom plate 10 located on the soil backing side is a toe plate 12.

Specifically, referring to fig. 1, taking three risers 20 as an example, the three risers 20 include a first riser 22, a second riser 23, and a third riser 24. For the first riser 22, the part of the bottom plate 10 positioned on the soil facing side of the first riser 22 is a heel plate 11, and the other part of the bottom plate 10 positioned on the soil backing side of the first riser 22 is a toe plate 12; for the second-stage vertical plate 23, a part of the bottom plate 10 positioned on the soil facing side of the second-stage vertical plate 23 is a heel plate 11, and the other part of the bottom plate 20 positioned on the soil backing side of the second-stage vertical plate 23 is a toe plate 12; for the third riser 24, the portion of the sole plate 10 on the earth facing side of the third riser 24 is the heel plate 11 and the other portion of the sole plate 10 on the earth facing side of the third riser 24 is the toe plate 12.

Further, the two vertical plates 20 can share the same bottom plate 10, and the planting soil body 50 in the accommodating groove 30 between the two vertical plates 20 can increase the weight of the gravity retaining wall, and improve the anti-sliding performance and anti-capsizing performance of the gravity retaining wall. It will be appreciated that sharing the same toe board 12 for both uprights 20 reduces material usage and reduces cost.

In some embodiments, the plurality of vertical plates 20 may also share the same bottom plate 10, which may improve the integrity of the gravity retaining wall; and a plurality of vertical plates 20 share the same wall toe board 12, so that the material use and the cost are reduced.

It should be noted that, during concrete construction, the bottom plate 10 and the vertical plate 20 may be reinforced concrete structures, and the concrete label is usually not lower than C30, so as to ensure the strength of the bottom plate 10 and the vertical plate 20, and meanwhile, the durability of the gravity retaining wall may be improved, so that the gravity retaining wall may have a better economic value. In some embodiments, other materials may be used for the bottom plate 10 and the vertical plate 20, so long as the strength requirements of the bottom plate 10 and the vertical plate 20 are guaranteed, which is not limited in this application.

The thickness of the bottom plate 10 can be calculated according to the bending resistance and shearing resistance of the gravity retaining wall based on the net counter force of the foundation 90, and the width of the bottom plate 10 along the Y direction can be checked according to the bearing capacity of the foundation 90, the overall stability, the anti-slip stability and the anti-capsizing stability of the gravity retaining wall, so as to ensure the supporting stability of the gravity retaining wall to the slope soil 70.

Further, referring to fig. 2 to 3, the gravity type retaining wall may further include a buttress 40, wherein the buttress 40 is located between two adjacent risers 20, and the buttress 40 is disposed at an angle to the risers 20. The bottom of the buttress 40 is connected with the bottom plate 10, at least one of two opposite sides of the buttress 40 connected with the bottom is connected with the vertical plate 20, the buttress 40 can divide the accommodating groove 30 into a plurality of planting grooves 31, and the planting soil body 50 is filled in each planting groove 31, so that plants can be planted in each planting groove 31 conveniently. Meanwhile, the buttress 40 can also be in a reinforced concrete structure, the concrete mark is not lower than C30, the integral strength of the buttress 40 is improved, and the durability of the buttress 40 is further improved. In some embodiments, other materials may be used for buttress 40, as long as the strength requirements of buttress 40 are met, and the present application is not limited.

The buttress 40 may be rectangular plate, and the bottom of the buttress 40 is connected with the bottom plate 10, and two opposite side walls connected with the bottom of the buttress 40 are respectively connected with two adjacent vertical plates 20, so that the supporting strength of the buttress 40 to the two adjacent vertical plates is improved, and meanwhile, the overall strength of the gravity type retaining wall is also improved, and the supporting stability of the gravity type retaining wall to the slope soil 70 is further improved. The angle between the buttress 40 and the upright plates 20 may be 90 degrees, and two buttress 40 may enclose a planting groove 31 (see fig. 2) formed in a square shape with the adjacent upright plates 20 for filling the planting soil body 50.

In some embodiments, the included angle between the buttress 40 and the vertical plate 20 may be an acute angle or an obtuse angle, so that the buttress 40, the vertical plate 20 and the bottom plate 10 form a triangular or quadrangular slot shape of the planting slot 31, and the diversity of the greening region modeling of the gravity retaining wall can be realized by limiting the slot shape of the planting slot 31; different green plants are planted in different planting grooves 31, so that diversity of planting types in a greening area of the gravity type retaining wall can be realized, and ornamental performance of the gravity type retaining wall is improved. Meanwhile, the triangular planting groove 31 can utilize the stability of the triangle to improve the overall strength of the gravity type retaining wall, and further improve the durability of the gravity type retaining wall.

Further, referring to fig. 2, a plurality of buttress walls 40 may be disposed between two adjacent upright plates 20, and each buttress wall 40 is connected to two adjacent upright plates 20 to enclose a plurality of square planting grooves 31; each planting groove 31 is filled with planting soil 50, and the planting soil 50 can be planted green to afforest the gravity retaining wall, so that the attractiveness of the gravity retaining wall is improved; meanwhile, different kinds of green plants can be planted in different planting grooves 31, so that the diversity of green plant planting is realized.

In an alternative embodiment, buttress 40 may be configured in a triangular shape and include a first right-angle side and a second right-angle side. The first right-angle edge of the buttress 40 can be used as the bottom of the buttress 40 to be connected with the bottom plate 10, and the second right-angle edge of the buttress 40 can be connected with the side wall of the riser 20 close to the heel plate 11, so that the connection stability between the riser 20 and the bottom plate 10 is improved, the overall strength of the gravity type retaining wall is improved, and the durability of the gravity type retaining wall is further improved.

Further, the adjacent two vertical plates 20, the adjacent two buttress walls 40 and the bottom plate 10 can be surrounded to form a planting groove 31 for filling the planting soil body 50, meanwhile, the two vertical plates 20 and the two buttress walls 40 are surrounded to form an opening 32 far away from the bottom plate 10, the opening 32 is communicated with the planting groove 31, the planting soil body 50 is conveniently placed in the planting groove 31, and green plants are planted in the planting soil body 50 and are positioned at the opening 32, so that the gravity retaining wall is beautified, and the ornamental value of the gravity retaining wall is improved.

Further, taking the base plate 10, the vertical plate 20 and the buttress 40 as examples, the vertical plate 20 and the buttress 40 can be provided with a plurality of vertical plates and fixedly connected with the same base plate 10, the overall strength of the gravity type retaining wall can be improved, and the durability of the gravity type retaining wall can be further improved.

The plurality of vertical plates 20 can be sequentially marked as a first vertical plate 22, a second vertical plate 23, … and an nth vertical plate along the Y direction and towards the direction of the slope soil body 70, the vertical plates 20 at each level are gradually increased, the planting soil body 50 for planting plants is respectively filled between the two adjacent vertical plates 20, and the heights of the two adjacent vertical plates 20 along the Z direction are different, so that gravity type retaining wall grading greening can be realized, and the attractiveness of the gravity type retaining wall is improved. Meanwhile, the gravity type retaining wall can be suitable for slope soil bodies 70 with different heights, and the applicability of the gravity type retaining wall is improved.

The multi-stage buttresses 40 are all perpendicular to the risers 20, each stage buttresses 40 are connected with two adjacent risers 20, the buttresses 40 supported and connected with the first stage riser 22 can be marked as a first stage buttresses 41, the buttresses 40 supported and connected with the second stage riser 23 can be marked as second stage buttresses 42, …, the buttresses 40 supported and connected with the nth stage riser 20 can be marked as an nth stage buttresses, and the buttresses 40 can be arranged to improve the supporting strength of the risers 20 and further improve the durability of the gravity retaining wall.

In some embodiments, when the height of the riser 20 in the Z direction is less than 6m, the riser 20 may not be provided with the buttress 40, so as to ensure the overall strength of the riser 20; the height limitation of the riser 20 can be set according to actual requirements, and the height of the riser 20 along the Z direction is not limited to be less than 6m, the riser 20 can be not provided with the buttress 40, the height of the riser 20 along the Z direction can be not less than 5m, 7m or 8m … …, and the like, the riser 20 can be not provided with the buttress 40, and the height can be specifically set according to actual requirements, and the height limitation is not limited in the application.

The vertical plates 20, the buttresses 40 and the bottom plate 10 are fixedly connected in pairs, so that the bending rigidity of the gravity type retaining wall can be increased, the deformation of the gravity type retaining wall in a normal use state and in an anti-seismic working condition is reduced, and the strength and the supporting stability of the gravity type retaining wall are improved; meanwhile, the structural size and the reinforcement amount of the gravity type retaining wall can be reduced, and the economic value of the gravity type retaining wall is improved.

Further, referring to fig. 1 to 3, the thickness and height of the first riser 22 and the first buttress 41 connected to the first riser 22 may be calculated based on the horizontal load of the limited range soil (the planting soil 50 in the planting groove 31 between the first riser 22 and the second riser 23 in the range of the heel plate 11 of the first riser 22 of the bottom plate 10) and without considering the beneficial effect of the soil in the passive region (the soil in the range of the toe plate 12 of the first riser 22 of the bottom plate 10; it should be noted that the soil in the range of the toe plate 12 of the first riser 22 may be the soil covering the bottom plate 10 or the soil may not exist) (the soil in the passive region and the limited range soil act on the first riser 22, and the acting force of the soil in the passive region to the soil in the passive region may counteract the acting force of a part of the limited range soil on the first riser 22).

Referring to fig. 1 to 3, in the case that there is no soil within the range of the toe plate 12 of the first riser 22, the first riser 22 only needs to bear the lateral pressure of the soil within a limited range, so that the first riser 22 and the first buttress 41 connected with the first riser 22 bear less external force, and the concrete usage and the reinforcement planting amount of the first riser 22 can be reduced on the basis of ensuring the overall strength and the support stability of the first riser 22, thereby saving the cost.

The thickness and the height of the second-stage vertical plate 23 and the second-stage buttress 42 connected with the second-stage vertical plate 23 to the n-1-stage vertical plate 20 and the n-stage buttress connected with the n-1-stage vertical plate 20 can be calculated according to the horizontal load of the soil body in a limited range and considering the beneficial influence of the soil body in a passive area, so that the external force born by the second-stage vertical plate 23 and the second-stage buttress 42 connected with the second-stage vertical plate 23 as well as the external force born by the n-1-stage vertical plate 20 and the n-1-stage buttress connected with the n-1-stage vertical plate 20 is reduced, the resistance is increased, and the strength of the gravity retaining wall and the supporting stability of the gravity retaining wall on the slope soil body 70 are further improved.

It should be noted that, the soil mass in the limited range under the stress of the second stage vertical plate 23 and the second stage buttress 42 connected to the second stage vertical plate 23 refers to the planting soil mass 50 in the planting groove 31 between the second stage vertical plate 23 and the third stage vertical plate, and the soil mass in the passive region refers to the planting soil mass 50 in the planting groove 31 between the first stage vertical plate 22 and the second stage vertical plate 23; the soil mass with limited range under the stress action of the n-1 stage vertical plate and the n-1 stage buttress connected with the n-1 stage vertical plate refers to planting soil mass 50 in the planting grooves 31 between the n-1 stage vertical plate and the n stage vertical plate, and the soil mass in the passive zone refers to planting soil mass 50 in all planting grooves 31 positioned at the corresponding positions of the toenail 12 of the n-1 stage vertical plate.

The thickness and the height of the nth stage vertical plate and the nth stage buttress connected with the nth stage vertical plate can be used for carrying out stress calculation according to the horizontal load of the slope soil body 70 and considering the beneficial effects of the soil body in the passive area (the planting soil bodies 50 in all planting grooves 31 at the corresponding positions of the wall toe plates 12 of the nth stage vertical plate); the resistance of the vertical plate and the buttress is increased, and the strength of the gravity type retaining wall and the supporting stability of the gravity type retaining wall to the slope soil body 70 are improved.

The soil between the first-level riser 22 and the n-1-level riser can be considered according to the soil with limited range, the lateral pressure of the planting soil 50 borne by the riser 20 can be reduced, the number and the size of the buttresses 40 can be correspondingly reduced, and the construction cost of the gravity retaining wall can be reduced. The nth stage vertical plate can consider the beneficial effect of the soil body of the passive area, the size and the reinforcement of the nth stage vertical plate positioned in the height range of the soil body of the passive area along the Z direction can be configured according to the construction requirement, and the size and the reinforcement of the vertical plate 20 positioned above the soil body of the passive area can be configured according to the stress calculation of the conventional cantilever plate component.

It should be noted that, the height of the vertical plate 20 along the Z direction may be determined according to the geology, engineering condition and landscape requirement of the slope soil 70, and is generally 4m-16m; the number of stages of the vertical plates 20 and the buttress 40 can be generally 2-5 stages, and in order to better realize gravity type retaining wall grading greening, the height difference of the adjacent vertical plates 20 can be generally 3-4 m; the specific parameter setting may be set according to actual requirements, which is not limited in this application.

Further, the thickness and height of the first riser 22 and the first buttress 41 attached to the first riser 22 may be based on the horizontal loading of a limited range of soil (limited range of soil refers to the planting soil 50 in the planting slot 31 between the first riser 22 and the second riser 23 on the heel plate 11 of the first riser 22) and the beneficial effects of passive zone soil (soil in the range of the toe plate 12 of the first riser 22 of the sole plate 10; it should be noted that soil in the range of the toe plate 12 of the first riser 22 may be soil that is covered on the sole plate 10 or that no soil may be present).

The thickness and height of the second-stage riser 23 and the second-stage buttress 42 connected to the second-stage riser 23 can be calculated from the horizontal load of a limited-range soil (limited-range soil refers to the planting soil 50 in the planting slots 31 between the second-stage riser 23 and the third-stage riser 24 on the heel plate 11 of the second-stage riser 23) and taking into account the beneficial effects of the passive-zone soil (passive-zone soil refers to the planting soil 50 in all the planting slots 31 on the toe plate 12 of the second-stage riser 23).

The thickness and height of the tertiary riser 24 and the tertiary buttress 43 connected to the tertiary riser 24 can be calculated based on the horizontal loading of a limited range of soil (limited range of soil referring to the slope soil 70 on the heel plate 11 of the tertiary riser 24) and taking into account the beneficial effects of passive zone soil (passive zone soil referring to the planting soil 50 in all planting slots 31 on the toe plate 12 of the tertiary riser 24). The three-stage vertical plates 20, the multi-stage buttress 40 positioned between two adjacent vertical plates 20 and the bottom plate 10 can divide the accommodating groove 30 into a plurality of planting grooves 31, planting soil bodies 50 are filled in the planting grooves 31, the planting soil bodies 50 provide soil and space of an organic planting layer required by plant production, the plurality of planting grooves 31 are respectively planted with green plants, and the external attractiveness of the gravity type retaining wall can be improved; the plurality of planting grooves 31 can also be used for planting different kinds of green plants respectively, so that the diversity of greening is improved, and the greening landscape requirement of the gravity retaining wall is met.

Further, the multi-stage riser 20 and the buttress 40 connected with the multi-stage riser 20 share the same bottom plate 10, so that the gravity of the riser 20, the buttress 40 and the planting soil 50 all acts on the bottom plate 10, and the anti-slip and anti-capsizing performances of the gravity retaining wall can be improved. The same base plate 10 can be seated on the foundation 90, and the foundation generally meets the load-bearing capacity requirement, so that the construction cost of the foundation 90 treatment of the filled area can be reduced.

Preferably, referring to fig. 1 and 2, taking three vertical plates 20, and three buttress walls 40 are disposed between two adjacent vertical plates 20 as an example, the three vertical plates 20 may include a first vertical plate 22, a second vertical plate 23 and a third vertical plate 24 disposed in sequence along the Y direction, and heights of the first vertical plate 22, the second vertical plate 23 and the third vertical plate 24 are gradually increased, and planting soil bodies 50 for planting green plants are respectively filled between the two adjacent vertical plates 20, so as to realize gravity type retaining wall grading greening, and improve the aesthetic property of gravity type retaining wall.

The first-stage buttress 41 can be arranged between the first-stage riser 22 and the second-stage riser 23, and the first-stage buttress 41 is connected with the first-stage riser 22 and the second-stage riser 23, so that the connection strength of the first-stage riser 22 and the second-stage riser 23 can be improved, and the integral strength of the gravity retaining wall can be improved. A second-stage buttress 42 can be arranged between the second-stage riser 23 and the third-stage riser 24, and the second-stage buttress 42 is connected with the second-stage riser 23 and the third-stage riser 24, so that the connection strength of the second-stage riser 23 and the third-stage riser 24 can be improved, and the integral strength of the gravity retaining wall can be improved.

It should be noted that, according to the extending lengths of the first stage riser 22, the second stage riser 23 and the third stage riser 24 along the X direction, a plurality of first stage buttresses 41 may be disposed between the first stage riser 22 and the second stage riser 23, and a plurality of second stage buttresses 42 may be disposed between the second stage riser 23 and the third stage riser 24, so as to improve the connection strength of the first stage riser 22, the second stage riser 23 and the third stage riser 24, and further improve the overall strength of the gravity retaining wall and the durability of the gravity retaining wall.

Further, the heel plate 11 of the third riser 24 may be provided with a plurality of third-stage buttresses 43 connected with the third riser 24, the third-stage buttresses 43 may be provided in a triangular shape, one straight edge portion of the third-stage buttresses 43 is connected with the bottom plate 10 as a bottom, the other straight edge portion of the third-stage buttresses 43 is connected with the third riser 24, and the connection strength of the third riser 24 and the bottom plate 10 is improved, so that the overall strength of the gravity retaining wall is improved.

Referring to fig. 1 to 3, the first standing plate 22, the second standing plate 23, the third standing plate 24, the first standing wall 41, the second standing wall 42, the third standing wall 43 and the bottom plate 10 may enclose a plurality of planting grooves 31, the planting soil 50 may include planting layers (not shown in the drawings) respectively filled in each planting groove 31, so that green plants are located at positions of the planting grooves 31 close to the openings 32, and the aesthetic property of the gravity retaining wall is improved. The green plants can comprise herbaceous plants and small woody plants, and can be planted according to actual requirements, and the application is not limited.

Further, referring to fig. 3, the planting soil body 50 further includes a reverse filter layer and a water-proof layer, wherein the reverse filter layer is filled at a side of the planting layer away from the opening 32 and is located between the water-proof layer and the planting layer. It will be appreciated that the planting soil 50 is comprised of a planting layer, a counter-filter layer (not shown) and a water barrier layer (not shown). The planting layer comprises organic planting layer soil, and the organic planting layer soil provides required organic matters for plant production, so that green plants are luxuriant to grow.

Further, referring to fig. 1 to 3, a plurality of drainage holes (not shown) are formed in the upright plates 20, the drainage holes penetrate through two opposite sides of each upright plate 20 along the Y direction, and the outward inclination gradient of the drainage holes is not less than 5%, so that water can flow along the inclination angle of the extending shaft of the drainage holes under the action of gravity.

The plurality of water discharge holes on each vertical plate 20 may be arranged at intervals along the X direction, and may be arranged at intervals along the Z direction away from the bottom plate 10 in an array or in a dot shape. The drain hole is communicated with the reverse filtering layer, so that the excessive water in the planting layer can be conveniently and smoothly discharged from the drain hole.

It should be noted that, each planting groove 31 is provided with a filtering layer, the length along the X direction between two adjacent buttresses 40 between two adjacent risers 20, the filtering layer may extend along the direction consistent with the extending direction of the length between two adjacent buttresses 40, and the filtering layer may be provided with a plurality of drainage holes, and the number and positions of the drainage holes may be set according to actual requirements, which is not limited in this application.

Further, each planting groove 31 may be provided with a plurality of inverted filter layers and a plurality of water-resisting layers along the Z direction, and the inverted filter layers and the water-resisting layers are stacked in a crossing manner along the Z direction, and each inverted filter layer needs to be communicated with the water draining holes, so that the water draining holes on each vertical plate 20 may be distributed in an array or in a dot shape; specifically, the plurality of water discharge holes on each vertical plate 20 may be rectangular or quincuncial, and may be set according to actual requirements, which is not limited in this application.

The reverse filter layer is composed of graded gravel with different grain sizes from thick to thin along the water flow direction (along the Y direction towards the direction far away from the slope soil body 70), has good water permeability, can provide a drainage channel for the redundant water in the planting layer, and ensures that the planting soil body 50 positioned in the planting groove 31 is not lost. The water-resisting layer is composed of rammed clay, so that excessive water in the planting layer can be smoothly discharged from the water discharge hole, the water can be prevented from being deposited on the planting layer to cause plant death, the water pressure can be dredged, fine soil particles can be prevented from being taken away, and the safety of the retaining wall supporting structure is guaranteed.

Further, referring to fig. 3, a plurality of inverted filter layers, a plurality of water-proof layers and planting layers can be stacked between two adjacent vertical plates 20 along the Z direction, and the inverted filter layers and the water-proof layers are stacked in a crossing manner along the Z direction. And the plain soil 75, the geotextile 80 and the reverse filtering layer are sequentially arranged between two adjacent water-resisting layers along the Y direction and in the direction close to the slope soil body 70, and the geotextile 80 can realize better isolation, reverse filtering and drainage functions. Specifically, geotextile 80 can isolate plain soil 75 from the counter-filtration layer; and can prevent the plain soil 75 from entering the reverse filtering layer, and further can prevent the water and soil loss of the plain soil 75 so as to maintain the structural stability of the plain soil 75; meanwhile, the water in the plain soil 75 can be discharged into the reverse filtering layer through the geotechnical cloth 80 and flows out through the water discharge holes communicated with the reverse filtering layer, so that the water can be prevented from accumulating in the planting layer to cause plant death, and the water pressure can be relieved.

Referring to fig. 3, a water-proof layer and a planting layer, plain soil 75, geotextile 80 and a reverse filtering layer along the Z-direction and between the planting layer and the water-proof layer may be disposed between the first stage riser 22 and the second stage riser 23. The counter-filtration layer may comprise a first counter-filtration layer 521, the water barrier may comprise a first water barrier 531, and the planting layer may comprise a first planting layer 511; the first water-resisting layer 531, the first inverse filter layer 521 and the first planting layer 511 are sequentially arranged along the Z direction and along the direction far away from the bottom plate 10, the soil 75, the geotechnical cloth 80 and the first inverse filter layer 521 are sequentially arranged between the first planting layer 511 and the first water-resisting layer 531 along the Y direction, the first inverse filter layer 521 is close to the first vertical plate 22, the thickness along the Y direction is not less than 500mm (in some embodiments, the thickness of the first inverse filter layer 521 along the Y direction can also be 200mm, 300mm or 600mm, etc., and can be set according to actual requirements, the application is not limited), and the position on the first vertical plate 22 corresponding to the first inverse filter layer 521 is provided with a drain hole, which is denoted as a first drain hole 211, and the excessive water in the first planting layer 511 can be smoothly discharged from the first drain hole 211.

Two inverted filter layers, two water-proof layers and one planting layer can be arranged between the second-stage vertical plate 23 and the third-stage vertical plate 24 along the Z direction. The counter-filtration layer may include a second first counter-filtration layer 522 and a second counter-filtration layer 523, the water barrier layer may include a second first water barrier layer 532 and a second water barrier layer 533, and the planting layer may include a second planting layer 512. The second water-blocking layer 532, the second water-blocking layer 533, and the second planting layer 512 are sequentially disposed along the Z-direction and toward a direction away from the bottom plate 10.

Specifically, the plain soil 75, the geotechnical cloth 80 and the second first inverse filter layer 522 are sequentially disposed between the second first water-blocking layer 532 and the second water-blocking layer 533 along the Y direction, the second first inverse filter layer 522 is close to the second stage riser 23, and the thickness of the second first inverse filter layer 522 along the Y direction is not less than 500mm (in some embodiments, the thickness of the first inverse filter layer 521 along the Y direction may also be 200mm, 300mm or 600mm, etc., which may be set according to the actual requirement, and the present application is not limited thereto); between the second water-proof layer 533 and the second planting layer 512, the plain soil 75, the geotechnical cloth 80 and the second reflective layer 523 are sequentially arranged along the Y-proof line, and the second reflective layer 523 is close to the second stage riser 23, and the thickness along the Y-direction is not less than 500mm (in some embodiments, the thickness of the first reflective layer 521 along the Y-direction may also be 200mm, 300mm or 600mm, etc., which may be set according to actual requirements, which is not limited in this application).

Two water discharge holes, which are respectively denoted as a second first water discharge hole 212 and a second water discharge hole 213, may be provided on the second stage riser 23; the second drain hole 212 can communicate the second first filter layer 522 with the first filter layer 521 along the Y direction in a direction away from the bottom plate 10; the water in the second filter layer 522 may flow into the first filter layer 521 through the second drain hole 212 and be discharged through the first drain hole 211. The second drain hole 213 is communicated with the second filter layer 523 and is located on the first planting layer 511, and can drain the moisture in the second filter layer 523 to the first planting layer 511 through the second drain hole 213 to irrigate the first planting layer 511, so as to provide moisture required by green planting growth.

In some embodiments, a plurality of water draining holes may be provided, and part of the water draining holes are communicated with the second first filtering layer 522, and the other part of the water draining holes are communicated with the second filtering layer 523, and the number and the positions of the water draining holes may be set according to practical situations, which is not limited in the application.

Three inverted filter layers, four water-resistant layers and one planting layer can be arranged between the third vertical plate 24 and the slope soil body 70 along the Z direction. The filtration layers include a third first filtration layer 524, a third second filtration layer 525, and a third filtration layer 526, which may include a third first water barrier 534, a third second water barrier 535, a third water barrier 536, and a third fourth water barrier 537. The third first water-blocking layer 534, the third second water-blocking layer 535, the third water-blocking layer 536 and the third fourth water-blocking layer 537 are sequentially disposed in the Z direction and in a direction away from the base plate 10; three drain holes, respectively designated as a third first drain hole 214, a third second drain hole 215, and a third drain hole 216, may be provided in the third riser 24.

Specifically, the plain soil 75, the geotechnical cloth 80 and the third first reverse filtering layer 524 are sequentially disposed between the third first water-blocking layer 534 and the third second water-blocking layer 535 along the Y direction, the third first reverse filtering layer 524 is close to the third riser 24 and has a thickness along the Y direction not less than 500mm (in some embodiments, the thickness of the first reverse filtering layer 521 along the Y direction may also be 200mm, 300mm or 600mm, etc., and may be set according to actual requirements, which is not limited in the present application); a plain soil 75, geotextile 80 and a third second reverse filtering layer 525 are sequentially arranged between the third second water-proof layer 535 and the third water-proof layer 536 along the Y direction, the thickness of the third second reverse filtering layer 525 along the Y direction is not less than 500mm (in some embodiments, the thickness of the first reverse filtering layer 521 along the Y direction can also be 200mm, 300mm or 600mm, etc., and can be set according to actual requirements, and the application is not limited); the plain soil 75, the geotextile 80 and the third three-reflection layer 526 are sequentially arranged between the third three-isolation layer 536 and the third four-isolation layer 537 along the Y direction, the thickness of the third three-reflection layer 526 along the Y direction is not less than 500mm (in some embodiments, the thickness of the first one-reflection layer 521 along the Y direction can also be 200mm, 300mm or 600mm, etc., and can be set according to actual requirements, and the application is not limited); part of the slope soil 70 may be pressed against the third four water-resistant layer 537.

The third drain hole 214 may communicate the third first filter layer 524 with the second filter layer 522 in the Y direction away from the bottom plate 10; moisture within the third filter layer 524 may flow into the second filter layer 522 through the third drain hole 214; the third drain hole 215 can be communicated with the third second reverse filtering layer 525 and the second reverse filtering layer 523; moisture in the third second counter filter layer 525 may flow into the second counter filter layer 523 through the third drain hole 215; the third water drain hole 216 is communicated with the third three-filtering layer 526 and is located on the second planting layer 512, and the water in the third three-filtering layer 526 can be discharged to the second planting layer 512 through the third water drain hole 216 so as to irrigate the second planting layer 512 and provide the water required by green planting growth.

Further, the third riser 24 contacts the slope, and the geotextile 80 is disposed between the third riser 24 and the slope, the geotextile 80 can separate the slope soil 70 from the reverse filtering layer and the water-proof layer, and the geotextile 80 has functions of reinforcement, filtering, drainage, protection and seepage prevention, can drain the water in the slope soil 70 to the third first reverse filtering layer 524, the third second reverse filtering layer 525 and the third reverse filtering layer 526, and can drain the water through the third first drainage hole 214, the third second drainage hole 215 and the third drainage hole 216.

It should be noted that, the number of the reverse filtration layers and the number of the water-resistant layers between the two adjacent vertical plates 20 along the Z direction may be set according to actual requirements, which is not limited in the present application; meanwhile, the number of the water draining holes on each vertical plate 20 can be set according to actual requirements, and the method is not limited in the application.

In some embodiments, only the anti-filtration layer may be disposed between two adjacent water-resistant layers disposed between two adjacent vertical plates 20 along the Z direction, and may be specifically disposed according to practical requirements, which is not limited in this application. The bottom plate 10 is provided with sedimentation slots (not shown in the figure), the sedimentation slots are arranged at intervals along the X direction, and the gravity retaining wall also comprises filling materials (not shown in the figure); the filling material is filled in the settlement joint, the filling material can be asphalt hemp, and the asphalt hemp is filled in the settlement joint, so that free settlement and scalability of a plurality of sections of retaining walls are guaranteed, uneven settlement and temperature internal force of the bottom plate are reduced, and applicability and durability of the gravity retaining wall are improved.

In some embodiments, the kind of the filling material may be set according to actual requirements, which is not limited in this application.

Specifically, when the bottom plate 10 is constructed, the bottom plate 10 is provided with settlement joints along the length position of 10m to 15m along the X direction, foam plates with the thickness of 2cm are filled in the settlement joints, after the foundation concrete pouring is completed, the foam plates in the settlement joints are cleaned before the settlement joints are filled, and then asphalt hemp ribs are filled in the settlement joints.

Further, referring to fig. 1 to 3, the gravity type retaining wall is disposed on one side of the slope soil 70 along the extending direction of the slope soil 70, and the gravity type retaining wall is disposed on one side of the slope soil 70, and is filled with the slope soil 70 until a portion of the slope soil 70 can be pressed on the third four water-proof layer 537, so that the gravity type retaining wall contacts with the slope soil 70, and the effectiveness and stability of the gravity type retaining wall for supporting the slope soil 70 are improved.

The following describes the construction process of the gravity retaining wall:

first, processing the steel bars, wherein the steel bars can adopt two types of steel bars of HPB300 (hot rolled plain round steel bars with the yield strength of 300 MPa) and HRB400 (hot rolled ribbed steel bars with the strength standard value of 400 megapascals); in some embodiments, the types of the reinforcing steel bars can be set according to actual requirements, and the application is not limited. When the steel bar is cut, the length of the steel bar needs to be calculated in advance, so that broken end waste of the steel bar is reduced, and the construction cost of the gravity retaining wall is reduced; meanwhile, the welding quantity of the steel bars is reduced, and the strength of the steel bar connecting frame is improved; the welding of the reinforcing steel bars can adopt lap welding, and the length and the quality of the welding seam meet the specifications, so that the welding strength requirement of the reinforcing steel bars is met.

Second, the reinforcing bars are embedded in the toe plate 12, the heel plate 11, the vertical plate 20 and the buttress 40 in sequence, and the reinforcing bars can be bound and formed by using a plum blossom point binding method, so that the strength of the toe plate 12, the heel plate 11, the vertical plate 20 and the buttress 40 can be improved, and the supporting stability of the gravity type retaining wall can be further improved.

Thirdly, pouring the bottom plate 10, installing the pouring fixing plate of the bottom plate 10 (comprising the toe plate 12 and the heel plate), pouring by a concrete automobile pumping mould method, and vibrating and compacting by using an inserted vibrating rod. When the toe board 12 and the heel board 11 are cast, three layers can be cast. Specifically, when layering cloth, pouring a layer, pouring a second layer and then pouring a third layer, wherein the paving thickness is not more than 40cm; when the concrete is poured into the mould, the blanking is required to be uniform, the concrete is matched with the vibration, and the vibration and the blanking of the concrete are performed in a staggered way. The space between the settlement joints on the bottom plate 10 along the X direction is 10m-15m, the settlement joint positions are required to be provided with foam plates with the thickness of 2cm, and foundation concrete pouring is completed, the foam plates of the joints are firstly cleaned before the settlement joint is filled, the immersed asphalt hemp bars are filled in the full section, and the joint width is uniform, the joint body is vertical, the circumferential through is realized, the filling is compact, no hollow is formed, and the appearance is smooth.

Fourth, pouring the vertical plate 20 and the buttress 40, manually chiseling out cement mortar and loose and weak layers on the concrete surface of the joint of the multi-stage vertical plate 20 and the multi-stage buttress 40 on the bottom plate 10 after the concrete strength of the toe plate 12 and the heel plate 11 reaches more than 2.5MPa, and washing with water after roughening. The area of the fresh concrete exposed after roughening is not less than 75% of the total area. The fixed plates of the riser 20 and buttress 40 are then installed, concreted and the construction joint set.

When the fixing plate of the multistage vertical plate 20 is installed, water draining holes are needed to be installed, a circular PVC pipe with the diameter of 10cm can be embedded in the vertical plate 20 from the bottom plate 10 at intervals of 2m-3m along the Z direction, the circular PVC pipes are staggered at intervals of 2m-3m along the X direction, and meanwhile, the transverse slope of the water draining holes is 5%, and the water draining holes are wrapped with the water permeable geotextile. When the PVC pipe is installed, the PVC pipe can be fixed through the steel bars, the PVC pipe is tightly contacted with the vertical plate 20 template, the end face of the PVC pipe is required to form a corresponding inclined plane, slurry leakage can not occur around the PVC pipe in the concrete pouring process, and the panel formed by the concrete pouring process is smooth and even.

Fifth, the planting groove 31 is backfilled, and when the wall body concrete strength of the gravity retaining wall reaches 70% of the preset strength, the planting soil body 50 can be filled, the water-resisting layer, the reverse filtering layer and the planting layer are symmetrically filled in layers, and the layers are tamped in layers.

(1) The clay was first tamped in the planting groove 31, and the backfilled height was up to 200mm below the weep hole.

(2) Filling a graded gravel reverse filtering layer with the grain diameter from coarse to fine along the water flow direction upwards along the Z direction, wherein the thickness of the reverse filtering layer is determined according to the comprehensive consideration of the grading, the source, the application, the construction method and the like of the reverse filtering material; and (3) wrapping the reverse filtering layer and the PVC pipe at the water inlet of the water discharge hole by adopting permeable geotextile, and backfilling the position 200mm below the previous water discharge hole.

(3) And repeating the steps (1) and (2) until backfilling to the bottom of the planting layer, wherein the range of the planting layer is a 2m area from the top of the vertical plate 20 to the height of the vertical plate 20, and in some embodiments, the range of the planting layer is a other area from the top of the vertical plate 20 to the height of the vertical plate 20, and the range of the planting layer is not limited in this application.

(4) And finally, filling up an organic planting layer, backfilling to the required top elevation of the landscape, wherein the planting layer can be used for planting herbaceous plants and small woody plants, realizing the graded greening of the gravity retaining wall and improving the external aesthetic property of the gravity retaining wall.

The backfilling process is controlled and constructed strictly according to the construction process parameters of common soil. To prevent the riser 20 and the buttress 40 from being damaged by impact, the rolling machine should be manually paved within a distance of 1.5m from the riser 20 and be matched with a small compacting machine for rolling.

It should be noted that, the construction process of the gravity type retaining wall can be set according to practical situations, and the application is not limited.

In the description of the present application, it should be understood that the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context. Furthermore, in the description of the present application, unless otherwise indicated, "a plurality" means two or more. "and/or", describes an association relationship of an association object, and indicates that there may be three relationships, for example, a and/or B, and may indicate: a exists alone, A and B exist together, and B exists alone. The character "/" generally indicates that the context-dependent object is an "or" relationship.

The foregoing disclosure is only illustrative of the preferred embodiments of the present application and is not intended to limit the scope of the claims herein, as the equivalent of the claims herein shall be construed to fall within the scope of the claims herein.

Claims (10)

1. A gravity retaining wall, comprising:

a bottom plate;

the planting device comprises at least two vertical plates, wherein one ends of the vertical plates are fixedly connected with the bottom plate, the vertical plates extend along a first preset direction, two adjacent vertical plates are arranged at intervals along a second preset direction, the first preset direction is perpendicular to the second preset direction, and a containing groove for filling planting soil bodies is formed between the two adjacent vertical plates and the bottom plate.

2. The gravity-type retaining wall of claim 1, wherein the gravity-type retaining wall further comprises:

the buttress is positioned in the accommodating groove between two adjacent vertical plates, and the buttress and the vertical plates are arranged at an included angle; the bottom of the buttress is connected with the bottom plate, and at least one of two opposite sides of the buttress connected with the bottom is connected with the vertical plate.

3. The gravity retaining wall according to claim 2, wherein,

the bottom of the buttress is connected with the bottom plate, and two opposite sides of the buttress are respectively connected with two adjacent vertical plates.

4. The gravity retaining wall according to claim 3,

when the opposite sides of the buttress are respectively connected with the two adjacent vertical plates, at least two buttresses are arranged between the two adjacent vertical plates, the accommodating groove is divided into a plurality of planting grooves for filling planting soil bodies by the buttresses, and the planting grooves are provided with openings far away from the bottom plate.

5. The gravity retaining wall according to claim 1, wherein,

the vertical plate is gradually increased along the second preset direction.

6. The gravity retaining wall according to claim 1, wherein,

The planting soil body is filled in the accommodating groove, and the planting soil body at least comprises a planting layer.

7. The gravity-type retaining wall of claim 6, wherein the gravity-type retaining wall further comprises:

the planting soil body further comprises a reverse filtering layer and a water-resisting layer;

the anti-filtering layer is located the planting layer is kept away from the one side of the notch of holding tank, the water-resisting layer is located the anti-filtering layer is kept away from the one side of planting layer, just the anti-filtering layer is located the water-resisting layer with between the planting layer.

8. The gravity retaining wall according to claim 7,

the vertical plate is provided with a plurality of water draining holes, the water draining holes are distributed in an array or in a dot shape, and the water draining holes are communicated with the reverse filtering layer.

9. The gravity retaining wall according to claim 8, wherein,

a plurality of reverse filtering layers and a plurality of water-resisting layers can be stacked between the adjacent vertical plates along a third preset direction, and the reverse filtering layers and the water-resisting layers are arranged in a crossing manner along the third preset direction; the first preset direction and the second preset direction are perpendicular to the third preset direction.

10. The gravity retaining wall according to claim 1, wherein,

The bottom plate is provided with sedimentation slits which are arranged at intervals along the first preset direction; the gravity retaining wall further comprises a filling material; and the filling material is filled in the settlement joint.

Images