RU2501911C1 - Multi-tier avalanche structure with promenade terraces on scarp - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: multi-tier avalanche structure with promenade terraces on a scarp comprises reinforced concrete piles, reinforced concrete retaining walls, horizontal reinforced concrete boards that form tiers together with reinforced concrete retaining walls. It is equipped with Z-shaped reinforced concrete support stiffening ribs, each comprising the following monolithically connected components: a vertical support element of alternating height of cross section, increasing top-down, a lower support element, made in the form of a lower pilework and an upper horizontal reinforced concrete beam, installed on the elevation of the upper edge of the scarp and made in the form of an upper pilework, monolithically connected with the upper part of the vertical support element. The lower pilework is monolithically connected with the lower part of the vertical support element. Z-shaped reinforced concrete support stiffening ribs are arranged in the vertical plane, which is perpendicular to the plane of the scarp in the place of their adjacency to the scarp, and at the entire height of the scarp and monolithically installed by means of lower and upper pileworks at the lower thrust and upper anchored reinforced concrete piles in one row at the specified distance from each other at the scarp. The upper edge of each lower pilework is divided into two sections: a horizontal section, on one part of which, adjacent to the scarp, there is a vertical support element, and an inclined section. Horizontal reinforced concrete boards along their entire length of all tiers are made as cantilevered, are equipped with parapets and form promenade terraces. The lower horizontal reinforced concrete board forms a promenade terrace of the first tier and is installed onto horizontal sections of the upper faces of the lower pilework, at the same time it is installed onto those parts of horizontal sections of the upper faces of lower pileworks, which are free from vertical support elements. The lower part of the structure is equipped with a sloping reinforced concrete board, which is installed onto inclined sections of the upper faces of the lower pilework and is monolithically connected with the lower horizontal reinforced concrete board to form a low grade towards the base of the structure. Retaining reinforced concrete walls may be installed in inclined and/or vertical position, at the same time they are monolithically connected by their back sides with front end faces of vertical support elements of Z-shaped reinforced concrete support stiffening ribs. In their lower and upper parts the retaining reinforced concrete walls are monolithically connected with horizontal reinforced concrete boards of adjacent tiers, and the lower part of the retaining reinforced concrete wall of the first tier is monolithicaly connected with the lower horizontal reinforced concrete board. Retaining reinforced concrete walls of each tier, horizontal cantilevered reinforced concrete boards, the lower horizontal reinforced concrete board and the sloping reinforced concrete board are divided by thermal settlement joints in a single vertical plane, stretching between two adjacent Z-shaped reinforced concrete support stiffening ribs at the specified distance in two adjacent sections of the structure. Optionally in different convenient places along the specified height of the structure there are stair descents or escalators for movement from one tier to another and to the foot of the scarp. Stair descents comprise monolithically connected staircases and intermediate reinforced concrete landing platforms, and additional stair descents are installed on the sloping reinforced concrete board. Intermediate reinforced concrete landing platforms with staircases are arranged as adjoining the retaining reinforced concrete wall. Intermediate reinforced concrete landing platforms are arranged between each two horizontal cantilevered reinforced concrete boards to form a stair descent. In places of adjacency of horizontal cantilevered reinforced concrete boards - promenade terraces to staircases (or escalators) there are transition openings, which adjoin the retaining reinforced concrete walls, for the possibility to move pedestrians from promenade terraces onto staircases (or escalators) and back.

EFFECT: provision of reliable protection of a scarp against dangerous slope processes.

7 cl, 5 dwg

Description

The invention relates to hydraulic engineering, in particular to a multi-tier anti-rock structure with walking terraces on a cliff, which is intended primarily for use as engineering structures to protect the cliff from dangerous slope processes: landslide and talus, to use the structure for lifting - lowering to a cliff or from a cliff, as well as for walks on terraces along a cliff.

As a result of patent information research, information was found that landscape measures are being taken when equipping buildings with staircases and terraces on the slopes. However, no tiered structures were found that can be used to strengthen the cliff from destruction and at the same time to climb to the cliff and lower from the cliff.

Known barriers to hold falling stones according to copyright certificates: No. 678147, class. E02D 29/02, publ. 1979, No. 909021, class Е02Д 29/02, Pub. 1082, which contain enclosing shields installed on the berm parallel to the lower edge of the slope near its edge, and shock absorbing elements, one end attached to each enclosing shield, the other end attached to the anchor installed in the well.

Known anti-rock structure (see Tolmachev K.K. Highways. Special structures. M. ed. "Transport", 1986, S. 86-87), with a retaining wall and with the device behind it dumping from gravel or local soil reinforced with stone in order to prevent the destruction of the wall structure by stones falling from the upper slope.

Known corner reinforced concrete retaining wall according to patent No. 2250964, class. E02D 29/02, publ. 04/27/2005, which, like the previous analogues, is intended to protect structures from rock-talus and rock-landslide impacts, rockfalls and dumps of large individual stones, as well as water-stone mudflows and which consists of a face plate, foundation slabs and unloading devices made of reinforced concrete slabs. To keep the wall in a stable state and in the design position, the wall foundation plate is made with a sole in the form of a round-cylindrical surface and is fixed with anchors that are made inclined.

However, the above-described analogues in engineering design are intended to solve only one technical problem - to protect structures located at the level of the slope sole from rockfalls, while their designs are not without drawbacks: they are unreliable in operation and not durable.

The closest analogue to the claimed invention is a multi-story building according to patent No. 2376428, class. E04H 1/00, publ. December 20, 2009 bull. No. 35, which can be built on a cliff or slope and which contains a step foundation built into the slope / break / mounted on reinforced concrete piles, while horizontal reinforced concrete floor slabs, reinforced concrete retaining walls and longitudinal bearing walls are laid on the step foundation slope terraces installed foundation horizontal reinforced concrete slabs. Reinforced concrete slabs on one side are mounted on top of retaining walls, the other side are mounted on top of longitudinal load-bearing walls, while they are rigidly connected to them and are a continuation of the foundation of horizontal reinforced concrete slabs on each floor with the formation of tiers.

Similar features with the claimed invention are the presence of reinforced concrete piles, reinforced concrete retaining walls, horizontal reinforced concrete slabs, which form tiers together with reinforced concrete retaining walls.

However, the building, erected on a stepped foundation, requires the creation of special storage terraces on which piling equipment should be placed, which is associated, in the case of steeply falling cliffs, with large volumes of complex excavation work. In addition, the building is not intended to be erected on a steeply falling cliff according to the constructive engineering plan and does not provide for the protection of the cliff from landslide and talus processes.

The technical task of the proposed structure is the creation of a multi-tiered structure that provides reliable protection of cliffs, including coastal ones, over their entire height, from landslide and talus processes, while at the same time providing favorable and convenient conditions for safe and improved movement of pedestrians to the base of the cliff, to shore or beach area, facilitate pedestrian lifting from the base of the cliff, from the shore from the beach area, to the top of the cliff with the possibility of walking along the cliff along the terraces, location conjugated at different height breakage.

The problem is solved by a new set of essential features that provide reliable protection of the cliff from landslide and talus processes, as well as safe and improved movement of pedestrians along the cliff on all tiers, due to the fact that the structure, including reinforced concrete piles, reinforced concrete retaining walls, horizontal reinforced concrete slabs, forming together with reinforced concrete retaining walls, tiers (features similar to the closest analogue) are equipped with Z-shaped reinforced concrete supporting reinforcing ribs, each of which consists of from a vertical support element, continuously connected to each other, of variable cross-section height, increasing from top to bottom, a lower support element in the form of a lower pile grillage and an upper horizontal reinforced concrete beam in the form of an upper pile grillage, integral with the upper part of a vertical support element, moreover, Z-shaped reinforced concrete support stiffeners are located in a vertical plane perpendicular to the plane of the cliff at the point of contact with the cliff and the entire height of the cliff and monol They are clearly installed by means of the lower and upper pile grillages on the lower thrust and upper anchor reinforced concrete piles in a row at a predetermined distance from each other on a cliff, and the upper face of each lower pile grillage is divided into two sections: a horizontal section, on one part of which is adjacent to a cliff, a vertical support element is located, and an inclined section. The horizontal reinforced concrete slabs along the entire length of all tiers are cantilevered, equipped with parapets and form walking terraces, and the lower horizontal reinforced concrete slab forms a walking terrace of the first tier and is installed on horizontal sections of the upper faces of the lower pile grillage, while it is installed on those parts of horizontal sections of the upper faces of the lower pile grillages, which are free of vertical supporting elements, and the lower part of the structure is equipped with a sloping same ezobetonnoy plate which is mounted on the upper faces of the inclined portions of the lower pile and pile cap integrally connected to the lower horizontal reinforced concrete slab to form a gentle descent to the base structure. Retaining reinforced concrete walls can be installed in an inclined and / or vertical position, while "they are monolithically connected with their rear sides to the front end faces of the vertical supporting elements of Z-shaped reinforced concrete supporting stiffeners, in their lower and upper parts the retaining reinforced concrete walls are monolithically connected to horizontal reinforced concrete slabs of adjacent tiers, and the lower part of the retaining reinforced concrete wall of the first tier is monolithically connected to the lower horizontal reinforced concrete slab. Retaining reinforced concrete walls of each tier, horizontal cantilever reinforced concrete slabs, lower horizontal reinforced concrete slab and sloping reinforced concrete slab are separated by temperature-sedimentary joints in one vertical plane passing between these two Z-shaped reinforced concrete supporting reinforcing ribs of two adjacent sections of the structure Selectively in different convenient places along the entire height of the structure, staircases or escalators are located to move from one tier to and the other to the base of the cliff. Stair descents consist of monolithically connected staircases and intermediate reinforced concrete staircases, and additional stair descents are installed on the sloping reinforced concrete slab, moreover, intermediate reinforced concrete staircases with staircases are made adjacent to the retaining reinforced concrete wall, while the intermediate staircases are located between each two horizontal cantilever reinforced concrete slabs with the formation of a stair descent. At the junctions of horizontal cantilever reinforced concrete slabs in the form of walking terraces to staircases (or escalators), transitional openings are made adjacent to retaining reinforced concrete walls to allow pedestrians to move from walking terraces to staircases (or escalators) and vice versa. The length of each individual section is set to a multiple of the distance between adjacent Z-shaped reinforced concrete support stiffeners of one section. The angle of inclination of the inclined position and / or the vertical position of the longitudinal reinforced concrete retaining walls are set depending on the steepness of the cliff. The upper horizontal reinforced concrete beam in the form of an upper pile grillage is installed at the mark of the upper edge of the cliff. The number of tiers and, accordingly, horizontal reinforced concrete slabs in the form of walking terraces is set depending on the height of the cliff. Each staircase descent within each tier may have one or more intermediate staircases and, accordingly, two or more flights of stairs. Stairs (or escalators) are set to a width less than the width of the walking terraces.

In the claimed invention, the specified set of structural features, the main of which is the presence and execution of a Z-shaped reinforced concrete support stiffeners, allows to generally obtain an improved technical result, since a Z-shaped reinforced concrete support stiffeners together with retaining reinforced concrete walls, horizontal reinforced concrete slabs, lower horizontal reinforced concrete slab form a rigid spatial frame within each section, separated by temperature-siege seams in one vertical plane, which ensures a stable position of the entire structure of the structure on the cliff and reliable protection of the cliffs along their entire height from landslide and talus processes. Terraces with transitional openings, stair descents, including flights of stairs and landings, together with sloping reinforced concrete slabs with an additional stair descent made at the bottom of the structure, installed on inclined sections of the lower pile grillage and its monolithic connection with the lower horizontal reinforced concrete slab provides convenience and comfort for pedestrians when lifting them to a cliff and when descending from a cliff.

The drawing schematically shows the structure, where:

figure 1 - shows the structure in a perspective view, a General view;

figure 2 is the same, fragmentary shows the internal elements of the structure;

figure 3 is the same, a section along aa between the Z-shaped reinforced concrete support stiffening ribs in figure 2;

figure 4 is the same, a section along BB along a Z-shaped reinforced concrete support stiffener.

Figure 5 is the same front view, a fragment of the section.

The construction includes upper reinforced concrete piles 1 and lower reinforced concrete piles 2, retaining reinforced concrete walls 3, horizontal cantilever reinforced concrete slabs 4 with parapets 5, lower horizontal reinforced concrete slab 6, sloping reinforced concrete slab 7 (see Fig. 2) and tiers 8 (Fig. 3 and 4).

The upper reinforced concrete piles 1 according to their functional purpose are anchor, the lower reinforced concrete piles 2 are resistant and installed in the same vertical plane on the upper and lower edges of the cliff, respectively.

The lower thrust and upper anchor reinforced concrete piles 1 and 2, respectively, are monolithically installed in one row and at a given distance from each other, for example, at a distance of 7-10 m on a cliff and to the entire cliff height by means of the lower and upper pile grillages Z -shaped reinforced concrete support stiffening ribs 9, each of which is located in a vertical plane perpendicular to the plane of the cliff at the point where they adjoin the cliff.

Each Z-shaped reinforced concrete support stiffener consists of a monolithically connected vertical support element 10 of variable cross-section height, increasing from top to bottom, a lower support element made in the form of a lower pile grillage 11, the upper face 12 of each lower pile grillage is divided into two section: horizontal section 13, on one part of which adjacent to the cliff, there is a vertical supporting element 10, and an inclined section 14, on which there is a sloping reinforced concrete slab and 7, and the upper horizontal reinforced concrete beam, made in the form of an upper pile grill 15, which is installed at the mark of the upper edge of the cliff perpendicular to it and is integral with the upper part of the vertical support element 10, and the lower support element in the form of a lower pile grill 11 is integral with the lower part of the vertical supporting element 11 of the Z-shaped reinforced concrete supporting stiffening ribs.

Horizontal reinforced concrete slabs 4 along the entire length of all tiers 8 are made cantilevered, equipped with parapets 5 and form walking terraces, while the number of tiers 8 and, accordingly, the number of horizontal cantilevered reinforced concrete slabs 4 forming walking terraces are set depending on the height of the cliff. The height of each tier 8 is taken no lower than, for example, 2.5-3 m, for the possibility of unhindered and safe movement of pedestrians on the terraces. For example, if the height of the cliff is 15 m, the number of tiers is taken to be five, i.e. the height of each tier is 3 m, and at a cliff height of 25 m, the number of tiers is taken to be eight.

The lower horizontal reinforced concrete slab 6 forms a walking terrace of the first tier and is installed on horizontal sections 13 of the upper faces 12 of the lower support element, made in the form of a lower pile grillage 11, while it is installed on those parts of horizontal sections 13 of the upper faces 12 of the lower pile grillages 11, which are free of vertical support elements 10.

The lower part of the structure is equipped with a sloping reinforced concrete slab 7, which is installed on inclined sections 14 of the upper faces 12 of the lower pile grillage 11 and is seamlessly connected to the lower horizontal reinforced concrete slab 6 with the formation of a gentle descent to the base of the structure (cliff).

Retaining longitudinal reinforced concrete walls 3 can be installed in an inclined and / or vertical position, while the angle of inclination of the inclined position and / or vertical position is set depending on the steepness of the cliff. For example, when the steepness of the cliff is close to 90 °, the retaining reinforced concrete walls 3 are vertical, and when the steepness of the cliff is much less than 90 °, for example 75 °, the angle of inclination of the retaining reinforced concrete wall 3 takes 70-80 °. The retaining reinforced concrete walls 3 are monolithically connected with their rear sides 16 to the front end faces 17 of the vertical supporting elements 10 of the Z-shaped reinforced concrete supporting ribs 9. In the lower and upper parts, the retaining reinforced concrete walls 3 are monolithically connected to the horizontal cantilever reinforced concrete plates of 4 adjacent tiers 8. The lower part of the retaining reinforced concrete wall 3 of the first tier 8 is seamlessly connected to the lower horizontal reinforced concrete slab 6.

Selectively in different convenient places along the entire height of the structure, there are ladder slopes 18 (or it can be escalators, which are not shown on the drawing) to move pedestrians along the entire height of the structure, from one tier 8 to another, and to the base of the cliff. Stair descents 18 consist of monolithically connected staircases 19 and intermediate reinforced concrete staircases 20. Moreover, each staircase 18, within each tier 8, can have one or more intermediate staircases 20 and, accordingly, two or more staircases , which is set to a width smaller than the width of the walking terraces for the possibility of unhindered passage through the walking terraces, which are formed by horizontal cantilevered reinforced concrete slabs 4 in place of contiguity to the last flight of stairs or the escalator 19. For example, with a width of 1.5 m of the flight of stairs 19, the walking terrace 4 has a width of 3 m to allow unhindered passage through them at the junction of the latter to the flight of stairs 19 (or the escalator).

In the lower part of the structure on the sloping reinforced concrete slab 7 additional stair descents 22 are installed for the convenience of lowering pedestrians directly to the base of the cliff, to the shore, to the beach area.

The intermediate reinforced concrete staircases 20 with the flights of stairs 19 are made adjacent to the retaining reinforced concrete wall 3, while the intermediate reinforced concrete staircases 20 are located between each two horizontal cantilevered reinforced concrete slabs 4 with the formation of the staircase descent 18.

At the junctions of horizontal cantilever reinforced concrete slabs 4 in the form of walking terraces to staircases (or escalators), transitional openings 23 are made adjacent to retaining reinforced concrete walls 3 for the possibility of pedestrians moving from walking terraces to staircases 19 (or escalators) and vice versa. The width of the transitional openings is equal to the width of the flights of stairs (or escalators).

The structure is separated every 40-60 m by temperature-sedimentary joints 24, dividing the structure into separate sections 25. To create a temperature-sedimentary joint 24, two adjacent Z-shaped reinforced concrete support stiffeners 9 of two adjacent sections are installed with a gap of 2-4 cm, and retaining reinforced concrete walls 3 of each tier, also horizontal cantilever reinforced concrete slabs 4, lower horizontal reinforced concrete slab 6 and sloping reinforced concrete slab 7 are separated by temperature-sedimentary joints 24 in one vertical plane, passage boxes between two adjacent Z-shaped reinforced concrete support stiffeners 9 of two adjacent sections of the structure. The length of each individual section 25 is set to a multiple of the distance between adjacent Z-shaped reinforced concrete support stiffening ribs of one section.

Over the entire height of the structure between the cliff and retaining reinforced concrete walls 3 there is a drainage backfill 26, from the bottom of the structure under the lower horizontal reinforced concrete slab 6 and sloping reinforced concrete slab 7 there is a stone backfill 27.

The construction of the structure is as follows.

First, the lower thrust and upper anchor reinforced concrete piles 1 and 2 are installed in the same vertical plane. Then, on these reinforced concrete piles, the first Z-shaped reinforced concrete support stiffener 9 is erected, in the following order. First, its lower supporting element is installed - the lower pile grillage 11, which monopolizes the head parts of the lower piles 2. Two sections are formed on the upper face 12 of the lower pile grill 11: a horizontal section 13 adjacent to the cliff and an inclined section 14 for the possibility of installing a slant reinforced concrete on it plates 7. Then, on the part of the horizontal section 13 adjacent to the cliff, a vertical support element 10 is installed so that its lower part rests on the upper face 12 of the lower pile grillage 11, integral with they extend the vertical support element 10 with the lower pile grillage 11, continue to erect the vertical support element 10 and finish monolithic the upper part of the vertical support element 10. On the upper part of the vertical support element 10, the upper horizontal reinforced concrete beam, which is the upper pile grillage 15, which is perpendicular edge of the cliff, beyond it further, for example, by 3-5 m, and which the head parts of the upper anchor piles 1 are monolithic, thereby completing the construction first Z-shaped concrete support ribs 9.

Upon completion of the construction of the first Z-shaped reinforced concrete support stiffener 9 in the same sequence erect the adjacent Z-shaped reinforced concrete support stiffener 9.

After that, laying (filling) of large stone 27 at the base of the cliff between the lower pile grillages 11 is carried out, so that the stone filling 27 does not protrude beyond the planes passing along the upper faces 12 of the lower pile grillage 11. Then install the lower horizontal reinforced concrete slab 6, monolithically connect it with free horizontal sections 13 of the upper faces 12 of the lower pile grillages 11 of two adjacent Z-shaped reinforced concrete support ribs 9. In addition, the lower horizontal reinforced concrete pl 6 that is a walking terrace tiers of the first 8 buildings. Then, a sloping reinforced concrete slab 7 is installed and attached to the lower horizontal reinforced concrete slab 6 with an additional ladder descent 22 being executed on it. Moreover, the sloping reinforced concrete slab 7 is installed, integrally connecting it with the inclined sections 14 of the upper faces 12 of the lower pile grillages 11 of two adjacent Z-shaped reinforced concrete support ribs 9.

After that, they begin to erect a retaining reinforced concrete wall 3 of the first tier 8, while integrally connecting the rear side 16 of the reinforced concrete retaining wall 3 with the front end face 17 of the vertical supporting elements 10 of the Z-shaped reinforced concrete supporting reinforcing ribs, and the lower part of the retaining reinforced concrete wall 3 is monolithically connected to bottom horizontal reinforced concrete slab 6.

Then install a horizontal cantilever reinforced concrete slab 4 of the second tier 8, while monolithically connect it to the upper part of the retaining reinforced concrete wall 3 of the first tier. Then, a retaining reinforced concrete wall 3 of the second tier 8 is erected, while its lower part is monolithically connected to the horizontal cantilever reinforced concrete slab of the second tier 8.

In the same sequence, the installation of horizontal cantilever reinforced concrete slabs 4 and retaining walls 3 of overlying tiers to the uppermost tier 8 of the structure continues.

As the tiers of the structure 8 are erected after the installation of the horizontal cantilever reinforced concrete slab 4 of the subsequent tier 8 is completed, drainage material 26 is poured into the space between the retaining reinforced concrete wall 3 and so on over the entire height of the cliff and the entire structure.

In addition, as the retaining reinforced concrete walls 3 and horizontal cantilever reinforced concrete slabs 4 are erected, staircases 19 and intermediate staircases 20 of stair descents 18 (or escalator structures) are rigidly attached to them.

Then, in horizontal cantilever reinforced concrete slabs 4, transitional openings 23 are made so that they adjoin the retaining reinforced concrete wall 3, while the transitional openings 23 are set to a width equal to the width of the flights of stairs 19 (or escalators) to allow pedestrians to move from the walking terraces 4 to the staircases marches 19 (or escalators) and vice versa. At the edges of these openings 23, flights of stairs 19 and intermediate staircases 20, railings 21 of the staircase 18 are installed.

On the edges of each horizontal cantilever reinforced concrete slab 4 of each tier 8 parapets 5 are arranged with the formation of walking terraces of each tier 8.

Depending on the size of the structure and soil conditions, every 40-60 m., Temperature-sedimentary seams are made in the structure, dividing the structure into separate sections 25. For this, two adjacent Z-shaped reinforced concrete support stiffeners 9 are installed to each other with a gap between them , which is filled with elastic material, with the formation of a temperature-sedimentary seam, for example 2-4 cm. In addition, retaining reinforced concrete walls 3 of each tier 8, horizontal cantilever reinforced concrete slabs 4 and lower horizontal reinforced concrete the slab 6 and the sloping reinforced concrete slab 7 are also separated by temperature-sedimentary joints in one vertical plane passing between these two adjacent Z-shaped reinforced concrete support stiffeners 9, as a result of which the whole structure is divided by temperature-sedimentary seams into separate sections 25, each length sections is set to a multiple of the distance between adjacent Z-shaped reinforced concrete support stiffeners 9 of one section. The distance between two adjacent Z-shaped reinforced concrete support ribs 9 is 7-10 m.

The construction works as follows.

Horizontal cantilever reinforced concrete slabs 4 transfer the load to the retaining reinforced concrete walls 3, the latter in turn transfer the load to the Z-shaped reinforced concrete support stiffening ribs 9, which, being the main structural element of the structure, operate as columns loaded with longitudinal and bending loads. At the same time, the upper anchor reinforced concrete piles 1 protect them from overturning, which through the upper pile grill 15 and together with the lower thrust reinforced concrete piles 2 through the lower pile grill 11 hold the Z-shaped reinforced concrete supporting stiffeners 9, and the whole structure as a whole. This provides increased stability, strength and immutability of the position of the spatial structure of the entire structure as a whole, as well as protective anti-rock properties.

Protective anti-landslide properties of the structure are ensured by the presence of a number of Z-shaped reinforced concrete supporting reinforcing ribs 9, which together with horizontal cantilevered reinforced concrete slabs 4, lower horizontal reinforced concrete slab 6 and retaining reinforced concrete walls 3 form a rigid spatial frame and in conjunction with a stone backfill 27 and drainage Backfill 26 provides protection of the cliff from collapses, due to the fact that the structure keeps the cliff soil from falling (slipping, shedding) down. This occurs as a result of the fact that the retaining reinforced concrete wall 3 of each tier 8, enclosed between two Z-shaped reinforced concrete supporting reinforcing ribs 9 vertically and between two horizontal cantilever reinforced concrete slabs 4, works as a reinforced concrete slab trapped along the contour. At the same time, surface water and groundwater pass through a drainage and stone backfill and flow down freely to the base of the cliff and structure.

The operation of a multi-tier anti-rock structure with walking terraces on a cliff is as follows.

In addition to the fact that horizontal cantilever reinforced concrete slabs 4 enhance the spatial rigidity of the structure, they at the same time represent walking terraces along which pedestrians move along the cliff on all tiers 8, and pedestrians use stair descents 18 or escalators to move from one tier 8 to another conventionally not shown in the drawing). Pedestrians ascending from the bottom up, first climb the additional stairway 22 on the sloping reinforced concrete slab 7 to the lower horizontal slab 6, which is the terrace of the first tier, then climb the flight of stairs 19, the intermediate staircases 20 (or the escalator) and go to the overlying horizontal cantilever reinforced concrete slab 4, which is also a walking terrace of the second tier 8, through the transitional opening 23, available in this slab 4.

In the same order, pedestrians move to the terraces of the next higher tiers 8. Pedestrians moving from top to bottom act in the opposite order.

Thus, the multi-tier anti-rock structure proposed for patenting with walking terraces on a cliff in comparison with the closest analogue and the analogues described above has several advantages:

1. Reliable protection of steep cliffs, including coastal ones, over their entire height from landslide and talus processes, is provided.

2. Provides increased stability of the entire multi-tiered structure.

3. Ensures the safety of people on the edge of the cliff with the preservation of all species surveys, landscapes below, on the horizon. Cliff protection allows you to maintain a safe area on the top of the cliff for placing arbors, awnings, benches, etc. with maximum and safe approach to the cliff edge.

4. Favorable and convenient conditions are provided for safe and improved descent to the base of the cliff, to the beach area or directly to the sea, or to the river.

Thus, conditions are provided for safe, convenient and comfortable descent of a pedestrian, for example, to the beach area or directly to the sea, as well as ascent, for example, from the beach area (or from the sea) to the top of the cliff.

5. There is the possibility of walking along the cliff along terraces located at different heights of the cliff.

6. The construction is economical, as:

- significantly reduced labor costs for its construction, firstly, due to combining the rock formations and stair descent with walking terraces, and secondly, the retaining reinforced concrete wall on each tier between two adjacent Z-shaped reinforced concrete supporting reinforcing ribs works like a plate clamped along contour, which allows to reduce its cross section;

- the territory adjacent to the cliff is preserved, it is possible to bring the buildings closer to the foot of the cliff and to the edge of the cliff;

- eliminates the need to place construction machines and mechanisms in tiers. All work can be performed by machines and mechanisms traveling only on the upper and lower platforms of the cliff.

- excluded large amounts of earthwork for placement on the terraces of piling equipment (as is the case in analogues);

In addition, the construction of a multi-tier anti-landslide structure with walking terraces on a cliff gives the landscape a special colorful look and attractiveness of the territory due to the possibility of walking on the terraces.

Thus, the multi-tiered construction proposed for patenting with walking terraces on a cliff has advanced technological capabilities, is comfortable and convenient in operation.

Analyzing the totality of design features in the present invention, it is clearly seen that these features are absent in the above-described analogues, as well as in the general level of hydraulic engineering construction and engineering protection of the territory from dangerous slope processes, and therefore, we can conclude that the "multi-level anti-slope structure with walking terraces on a cliff "is new, has an inventive step, is industrially applicable, is several times more economical than analogs and ensures the achievement of a new useful technique result.

Claims (7)

1. A multi-tier anti-rock structure with walking terraces on a cliff, including reinforced concrete piles, reinforced concrete retaining walls, horizontal reinforced concrete slabs forming tiers together with reinforced concrete retaining walls, characterized in that it is equipped with Z-shaped reinforced concrete supporting reinforcing ribs, each of which consists of monolithically connected to each other of a vertical support element of variable cross-sectional height, increasing from top to bottom, of the lower support element, made in the form the lower pile pile grillage and the upper horizontal reinforced concrete beam installed at the mark of the upper edge of the cliff and made in the form of the upper pile grillage, which is integral with the upper part of the vertical support element, and the lower pile grillage is integral with the lower part of the vertical support element, with Z-shaped reinforced concrete supporting stiffeners are located in a vertical plane perpendicular to the plane of the cliff, in the place where they adjoin the cliff and to the entire height of the cliff and by means of lower and upper pile grillages are mated to the lower thrust and upper anchor reinforced concrete piles in one row at a specified distance from each other on a cliff, and the upper face of each lower pile grill is divided into two sections: a horizontal section, on one part of which is adjacent to the cliff , there is a vertical supporting element, and an inclined section, and horizontal reinforced concrete slabs along their entire length of all tiers are made cantilever, equipped with parapets and form walking terraces, moreover, the lower horizontal reinforced concrete slab forms a walking terrace of the first tier and is installed on horizontal sections of the upper faces of the lower pile grillage, while it is installed on those parts of the horizontal sections of the upper faces of the lower pile grillages that are free of vertical supporting elements, the lower part of the structure is equipped with a sloping reinforced concrete a plate that is installed on the inclined sections of the upper faces of the lower pile grillage and is seamlessly connected to the lower horizontal reinforced concrete slab with the formation of a gentle descent to the base of the structure, and retaining reinforced concrete walls can be installed in an inclined and / or vertical position, while they are monolithically connected with their rear sides to the front end faces of the vertical supporting elements of the Z-shaped reinforced concrete supporting stiffeners, the lower and upper parts of the retaining reinforced concrete walls are seamlessly connected with horizontal reinforced concrete slabs of adjacent tiers, and the lower part of the retaining reinforced concrete wall the first tier is monolithically connected to the lower horizontal reinforced concrete slab, and the retaining reinforced concrete walls of each tier, the horizontal cantilever reinforced concrete slabs, the lower horizontal reinforced concrete slab and the sloping reinforced concrete slab are separated by temperature-sedimentary joints in one vertical plane passing between two adjacent Z- standing at a given distance shaped reinforced concrete support stiffeners of two adjacent sections of the structure, selectively in different convenient places along the entire height staircases or escalators are located to move from one tier to another and to the base of the cliff, staircases consist of staircases and intermediate reinforced concrete staircases that are seamlessly connected to each other, and additional staircases are installed on the sloping reinforced concrete slab, with intermediate reinforced concrete staircases with flights of stairs made adjacent to the retaining reinforced concrete wall, with intermediate reinforced concrete landings located Between each two horizontal cantilevered reinforced concrete slabs with the formation of a stair descent, at the junctions of the horizontal cantilevered reinforced concrete slabs - walking terraces to staircases (or escalators), transitional openings are made adjacent to the retaining reinforced concrete walls to allow pedestrians to move from walking terraces to staircases ( or escalators) and vice versa. 2. The structure according to claim 1, characterized in that the length of each individual section is set to a multiple of the distance between adjacent Z-shaped reinforced concrete support stiffening ribs of one section. 3. The structure according to claim 1, characterized in that the angle of inclination of the inclined position and / or the vertical position of the longitudinal reinforced concrete retaining walls are set depending on the steepness of the cliff. 4. The construction according to claim 1, characterized in that the upper horizontal reinforced concrete beam in the form of an upper pile grillage is installed at the mark of the upper edge of the cliff. 5. The construction according to claim 1, characterized in that the number of tiers and, accordingly, horizontal reinforced concrete slabs in the form of walking terraces are set depending on the height of the cliff. 6. The construction according to claim 1, characterized in that each staircase descent within each tier may have one or more intermediate staircases and, accordingly, two or more flights of stairs. 7. The construction according to claims 1 and 6, characterized in that the flights of stairs or escalators are set to a width less than the width of the walking terraces.

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