RU2215087C2 - Bank-protecting structure - Google Patents

Abstract

FIELD: hydraulic engineering; applicable in capacity of bank-protecting structure for prevention of river banks scouring, and river bed reformation and performance of river regulation. SUBSTANCE: bank-protecting structure consists of reinforced-rubble-concrete two-layer rubble masonry or two-layer rubble-concrete blocks of various lengths with reinforcing fabric and forming step structure with rising step height in direction to bank, with steps interconnected with high-strength mortar of concrete and divided in plan by structurally deformation seams into separate interconnected by reinforcing fabric reinforced-rubble-concrete blocks. Bank-protecting structure may consists of reinforced-rubble-concrete two-layer components or two-layer components of rubble-concrete of various lengths with reinforcing fabric and forming step structure with rising step heights towards bank and laid on one another without mortar. Adjacent from front side is flexible single-layer reinforced-rubble-concrete apron having in plan form of hexagon with trapezoidal end part. Bank-protecting structure may consist of reinforced-rubble-concrete masonry or masonry with rubble-concrete blocks laid on high-strength mortar, or concrete only over perimeter and over entire height of structural block with filling of internal space between layers of reinforcing fabric with filler. Sizes in plan towards river bank of structure may rise by steps or uniformly, and top face is flat in shape. Working reinforcement is provided in extended zone. EFFECT: provided reliable protection of inhabited localities from flooding and bank scouring with reduced expenditures for construction as compared with known structures. 5 cl, 15 dwg

Description

 The invention relates to hydraulic engineering and can be used as a shore protection structure to prevent erosion of river banks and the reformation of river channels with a view to regulating them.

A device is known for protecting the base of river bank protection structures from washing out [1], which is a continuous flexible design of an anti-erosion device that provides reliable protection of a bank protection structure in rivers, flood floods of which are characterized by high abrasive and conveying abilities. The device consists of gabion mattresses horizontally located in the direction of the river bed, connected to the protected structure by means of articulated joints, and on top of which are disposed tire covers, connected to each other by longitudinal and transverse reinforcing bars that form a connected grid and passing along and across the rows of tire covers through the middle of the tread parts of the tires by their diameter. When the channel erodes into the formed funnel, the mattress is self-immersed with a load, starting from its end. The disadvantages of this technical solution are:
lack of design flexibility when using it in the front of a half-dam and with significant deformations, a gap in the gabion mesh is possible;
design complexity caused by the presence of a large number of different materials, in particular the use of rubber that is not always available and widespread in large quantities;
the proposed technical solution does not provide protection against erosion of the wall along the entire length, since it is not a solid apron pivotally adjacent to the retaining wall.

The closest technical solution is a shore protection structure, consisting of a bulk dam with a combined sloping mount and anti-erosion devices [2], which are made in the form of short flooded spurs of length l = l ₁ + l ₂ , where l ₁ is the length of the root part of the spur, consisting of two or more layers of gabions, with l ₁ > l ₂ , where l ₂ is the length of the head of the part of the blinker, consisting of one layer of gabions, on top and in front of which flexible reinforced concrete lattices are attached, and l ₂ ≥2h _p , where h _p is the maximum depth of possible erosion p weakly below the base of the head portion spurs. Spurs are located at the foot of the dam at a distance from each other and their root parts are embedded in the fortified slope of the dam. The disadvantages of this technical solution are:
possible washing away of the end of the base of the spur with stream jets flowing around the barrier, which is a spur and, as a result, deepening it down and violating the integrity of the structure;
relative complexity and uneconomical technical solutions.

 The purpose of the invention is to increase operational reliability and reduce the complexity of construction.

 This goal is achieved by the fact that a layer of stones or concrete blocks is laid right at the bottom of the riverbed or canal, in the plan having a rectangular shape, which will become the base of the half-dam. A layer of high-strength mortar or concrete is laid on this layer, into which a reinforcing mesh is inserted, passing through the entire length of the future half-dam, and a close layer of stones or concrete blocks is again laid on top, while structural-expansion joints are provided in the structure that divide the structure into enlarged blocks . The enlarged blocks are interconnected by a reinforcing mesh passing through the entire half-dam. The reinforcing mesh has a high deformation ability and when stretched in one direction, it leads to compression of the concrete in the transverse direction, makes reinforced concrete work for compression, thereby increasing the bearing capacity of the structure as a whole. In this way, reinforced concrete two-layer layers of rubble masonry or two-layer layers of concrete blocks that have different lengths are mounted. As a result of the buildup of such layers of different lengths, a half-dam construction stepwise in cross section is formed, and the individual layers can be connected together dry either with high-strength mortar or concrete. Laying the layers on top of each other dry is carried out with a shift of the protruding stones in the upper and lower layers to enhance the adhesion and friction of the adjacent layers. In the concrete blocks, to enhance the adhesion of the layers to each other, protrusions and recesses are provided, which are mounted on top of each other during the installation process.

 On the front side of the half-dam adjoins a flexible single-layer reinforced concrete apron having a trapezoidal plan and overlapping a possible erosion pit. The flexible apron is divided by structural expansion joints into enlarged aggregated blocks interconnected by a reinforcing mesh. When the apron is deformed, the integrity of the structure is not violated due to the interconnection of each individual block from all four sides with the reinforcing mesh to the adjacent blocks. The semi-dam block design increases the flexibility of the apron design. Semi-dams change the kinematic structure of the flow in such a way that stagnation zones form on the coastal part of the earth dam and erosion stops, and in the immediate vicinity of the contact between the dams and the dam, siltation begins on its lower side. Suspended and entrained particles under the influence of their own weight begin to precipitate due to a decrease in the weighing force caused by a decrease in the flow rate. A half-dam enters the riding slope of the dam and is fixed in it. From the front side of the half-dam, the flow rates flowing around it increase and the process of washing away the flexible armored concrete apron begins, which, under the influence of its own weight, starts to fall down and prevent possible deformations of the half-dam itself. At the same time, the apron, sinking down, after erosion, after a while begins to wilter and turns into an anchor. The shape of the reinforced concrete apron is trapezoidal, which corresponds to the shape of the erosion pit formed by the stream streamlined around the barrier. Possible deformations of the semi-dam structure do not violate structural integrity and do not affect its operation due to the presence of structurally-expansion joints that make the structure of the structure flexible and changeable. The individual structural blocks are interconnected by a reinforcing mesh, which makes the construction of the semi-dam flexible.

 The half-dam of the shore protection structure can be mounted in such a way that reinforced concrete blocks with rubble masonry or brickwork from concrete concrete blocks are laid on a high-strength mortar or concrete only along the perimeter and along the entire height of the enlarged structural block, forming walls with filling the internal space between the layers of reinforcing meshes with aggregate in the form of crushed stone or stone. In this way, a semi-dam turns into cellular blocks with a filler interconnected by a reinforcing mesh. Aggregate pores are introduced or filled with soil, which leads to vegetation overgrowing during operation. Vegetation reinforces the entire inner space and secures the half-dam to the bottom of the channel.

 The half-dam of the shore protection structure can be mounted from reinforced concrete blocks with rubble masonry or brickwork from concrete concrete blocks laid on high-strength mortar or concrete, the dimensions of which in the direction toward the shore from the lower side increase stepwise or evenly, and the top face has a flat shape. In the stretched zone from the upper side of the half-dam, working reinforcement is provided, which perceives the tensile forces caused by the pressure of the flow on the cantilever part.

 Figure 1 shows a longitudinal profile along the axis of a half-dam made of reinforced concrete; figure 2 is the same plan; figure 3 is a section 1-1 in figure 2 for the option of connecting the layers between a solution or concrete; in Fig.4 is a section 2-2 in Fig. 2 for the option of connecting the layers together with mortar or concrete; figure 5 is a section 1-1 in figure 2 for the option of connecting the layers together dry with a shift of stones; in Fig.6 is a section 2-2 in Fig.2 for the option of connecting the layers together dry with a shift of stones; Fig.7 shows a longitudinal profile along the axis of a half-dam made of reinforced concrete, laid only around the perimeter with the filling of the internal space; in FIG. 8 - the same plan; figure 9 shows a longitudinal profile along the axis of the half-dam, made of concrete blocks; figure 10 shows a longitudinal profile along the axis of the half-dam, made of concrete blocks laid out only around the perimeter with the filling of the internal space; figure 11 is a section 3-3 in figure 10; in Fig.12 - node a in Fig.10; Fig.13 shows a plan of reinforced concrete half-dam, the dimensions of which in the plan in the direction towards the shore are stepwise reduced; on Fig depicts a half-dam plan of concrete blocks, the dimensions of which in the plan in the direction towards the shore are stepwise reduced; Fig. 15 shows a plan of reinforced concrete half-dam or half-dam of concrete concrete blocks, the dimensions of which in the plan towards the coast are gradually decreasing.

 The coastal protection structure consists of a bulk soil dam 1, in the uphill slope 2 of which a half-dam 3 is wedged in, consisting of reinforced concrete two-layer layers of rubble masonry 4 or two-layer layers of rubble-concrete sides 5. Armored concrete and double-layer layers of rubble masonry 4 or two-layer layers of rubble-concrete lateral 5 are interconnected or concrete 6, or fastened together dry 7. Armored concrete two-layer layers of rubble masonry 4 or two-layer layers of concrete concrete sides 5 are tightly laid stones 8 or concrete blocks 9 with high-strength mortar or concrete 10 with a reinforcing mesh 11. Half-dam 3 is divided in terms of structurally-expansion joints 12 into enlarged blocks 13, interconnected by reinforcing mesh 11, which runs through the entire half-dam 3. From the front side of the half-dam 3 adjoins a flexible single-layer reinforced concrete apron 14, broken by structural and expansion joints 12 into blocks and having a hexagonal shape with a trapezoidal end part 14, which when flowed around and a stream of multi-stage construction will be washed and deepened down. The enlarged blocks 13 can consist of walls 15 with rubble 8 masonry or masonry from concrete blocks 9, laid on a high-strength mortar or concrete 6 only along the perimeter and along the entire height of the structural enlarged block 13 with the filling of the inner space 16 between the layers of reinforcing mesh 11 with a filler in the form crushed stone or stone 17, the pores of which are introduced or filled with soil and overgrown during operation by vegetation 18. The concrete blocks 9 have protrusions 19 and recesses 20, which, when connected dry, reinforce the adhesion s between adjacent layers. In the upper face 21 of the half-dam 3, working reinforcement 22 is provided, and the lower face 23 may have a stepped shape or gradually expand in plan towards the shore.

 The shore protection structure is mounted and operates as follows. A layer of stones 8 or concrete blocks 9 is laid right at the bottom of the riverbed or canal, having a rectangular shape in plan. A layer of high-strength mortar or concrete 10 is laid on this layer, in which the reinforcing mesh 11 is located, and a close layer of stones 8 or concrete blocks 9 is re-laid on top, while structural and expansion joints 12 are provided in the structure, which break the structure into enlarged blocks 13, interconnected by a reinforcing mesh 11 passing through the entire half-dam 3. In this way, reinforced concrete two-layer layers of rubble masonry 4 or two-layer layers of concrete concrete blocks 5 are mounted, which have different length, as a result of which, forming a stepwise cross-sectional structure of the half-dam 3, and can be connected together dry either with high-strength mortar, or concrete 6. When laying layers on top of each other, dry 7 is carried out with a shift of the protruding stones 8 in the upper and lower layer to enhance the adhesion and friction of adjoining dry layers. In the concrete concrete sides, to enhance the adhesion of the layers to each other, protrusions 19 and recesses 20 are provided, which are mounted on top of each other during installation.

 A flexible single-layer reinforced concrete apron 14 adjoins on the front side of the half-dam 3, broken in terms of structural-expansion joints 12 into enlarged enlarged blocks 13. Half-dam 3 change the kinematic structure of the flow so that stagnation zones are formed at the coastal part of the earth dam 1 and the erosion process stops, and in the immediate vicinity of the contact of the half-dam 3 and dam 1, the siltation process begins on its lower side. Half-dam 3 enters the uphill slope 2 of dam 3. From the front side of half-dam 3, the flow velocities flowing around it increase, and the process of washing the flexible reinforced concrete apron 14 begins, which, under the influence of its own weight, starts to fall down and prevent possible deformations of the half-dam itself 3. The reinforced concrete concrete form the apron 14 is trapezoidal, which corresponds to the shape of the erosion pit formed by the streamlined stream. Possible deformations of the half-dam structure 3 do not violate structural integrity and do not affect its operation due to the presence of structural-expansion joints 12, which make the structure of the structure flexible and changeable.

 The half-dam 3 of the shore protection structure can be mounted in such a way that the reinforced concrete blocks with quarry masonry 4 or the masonry from concrete concrete blocks 5 are laid on a high-strength mortar or concrete 6 only along the perimeter and along the entire height of the enlarged structural block 13, forming walls 15 with the filling of the internal space 16 between layers of reinforcing mesh 11 aggregate in the form of crushed stone or stone 17. The pores of the filler are introduced or filled with soil, which leads to overgrowing during operation by vegetation 18, the root system the theme of which reinforces the inner space 16 and secures the half-dam 3 to the bottom of the channel.

 The half-dam 3 of the shore protection structure can be mounted from reinforced concrete blocks with rubble masonry 4 or masonry from concrete concrete blocks 5 laid on a high-strength mortar or concrete 6, the dimensions of which in the plan toward the coast from the lower 23 side are stepped or evenly increase, and the upper face 21 flat shape. In the stretched zone from the upper side 21 of the half-dam 3, a working armature 22 is provided, which accepts tensile forces caused by the pressure of the flow on the cantilever part.

 This shore protection structure can be used on mountain and lowland rivers. If the stone is the local building material, then half-dam is more economical to perform reinforced concrete, this is usually possible on mountain rivers. If the stone is an expensive building material, then a half-dam can be built from buton concrete blocks of a cellular structure with the filling of the internal space with local material. The shore protection structure can also be used as a straightening structure for regulating river channels.

 The proposed design of semi-dams with decreasing dimensions in terms of the plan will significantly save construction costs and make the design more economical and reliable in operation.

 The shore protection construction will provide reliable protection against flooding and erosion during flood costs of settlements falling into this zone.

Sources of information
1. A. p. 1583515 USSR, MKI E 02 3/12. A device for protecting the base of river bank protection structures from washing out / S.O. Kurbanov, V.V. Zmeeva, Z. A. Ozrokova and E.A. Torshin (USSR). Application 04/05/88; publ. 08/07/90. Bull. 29.

 2. Patent of the Russian Federation 2103440, MKI E 02 3/12. Coast protection construction / S.O. Kurbanov, E.A. Torshina; publ. 01/27/98. Bull. 3.

Claims (5)

 1. A coastal protection structure containing made of blocks of different lengths, forming a step structure with step heights increasing towards the shore and containing reinforcing mesh and stones, characterized in that the blocks are made of reinforced concrete two-layer layers of rubble masonry or two-layer layers of but concrete blocks with reinforcing mesh and interconnected by high-strength mortar or concrete, divided by structural-expansion joints into separate enlarged aggregated blocks, and from the front side They are adjacent to them by a flexible single-layer reinforced concrete apron, broken in plan into coarse-grained aggregated blocks.  2. The shore protection structure according to claim 1, characterized in that the reinforced concrete and concrete concrete blocks of different lengths forming a stepped structure are laid on top of each other dry with a shift of protruding stones in the upper and lower layer or by connecting protrusions and recesses in the concrete blocks to enhance adhesion and friction of adjoining dry layers.  3. The shore protection structure according to claim 1, characterized in that the reinforced concrete apron is made in plan in the form of a hexagon with a trapezoidal end part.  4. The shore protection structure according to claim 1, characterized in that the reinforced concrete or but concrete blocks are connected by a high-strength mortar or beta along the perimeter and along the entire height of the enlarged block with the filling of the internal space between the reinforcing mesh layers with aggregate in the form of crushed stone or stone.  5. The shore protection structure according to claim 1, characterized in that the reinforced concrete or concrete blocks are made in plan with stepwise or uniformly increasing dimensions, with the top part having a flat shape, and with working reinforcement in the stretched zone.

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