RU2026451C1 - Bank protection, slope protection and retainer holding facility - Google Patents

Abstract

FIELD: water-development works. SUBSTANCE: bank protection, slope protection and retainer holding facility has facing slabs 1-1′ of rectangular or square configuration with reinforced films made of polymer materials rigidly embedded in each frame 2 over perimeter. Slabs 1-1′ adjoin one another longitudinally and are coupled and rigidly secured both to front profiled bars 4 of abutment frames 5-5′ and relative to one another by means of anchor ties and inserted parts by the tops of each of adjacent slabs 1-1′ and in middle portion along their length 7. Front profiled trapezoidal bars 1 are rigidly secured to similar lower bars 9 and rear bars 10 by means of ties; bars 4, 9 and 10 are engageable relative to one another by their end fins on the side of their constricted faces and form in each abutment row (in the section of the facility) abutment frames 5-5′ mounted in succession in vertical plane and adjoining each other by end fins of widened faces 16 of engageable lower bars 9 and rear bars 10. Front bars 4 of frames 5-5′ and facing slabs 5′ are oriented in plane of slope 17. Lower abutment frames 1-1′ of each row are deepened to non-washable depth - below the level of low waters with facing slabs 1′ mounted on them. Lower bars 9 are coupled together by their widened faces 16. Each row of abutment frames 5-5′ is mounted in the slops cut beforehand in slope 17. Joints of adjacent slabs 1-1′ are embedded in cement and slots with abutment frames 5-5′ mounted in them are filled with local or draining soil. EFFECT: enhanced reliability. 3 cl, 11 dwg

Description

 The invention relates to hydraulic engineering, to the construction of engineering structures for strengthening slopes, slopes, slopes, as well as retaining retaining walls, and in particular to a shore-protecting, sloping and retaining-retaining structure.

 The closest in technical essence and the achieved result is the prefabricated wall of the quay embankment.

 The prefabricated wall contains enclosing plates mounted in the front beams of buttress trusses with triangular frames, both the truss and its frames are made of triangular equilateral shape. The buttress trusses installed in the line of the embankment are connected by embedded bars, located at a distance from each other along the wall length of up to 2.0 meters, and the enclosing plates are made of 2 types, namely: above the water horizon - reinforced concrete, below the water horizon - wooden.

The length of the farm is 11.25 m, the height is 7.1 m. The disadvantages of this technical solution:
- buttress farms require special means for their delivery and installation work, which limits their use;
- the design requires large volumes of backfilling of the embankment, as well as the development of soil under the wall, which increases the cost of construction;
- buttress farms weakly involve passive resistance to soil due to the rectangular cross section of its beams;
- the use of wooden shields leads to their rapid decay, which entails additional costs for their repair and replacement;
- railway plates require a significant consumption of reinforced concrete;
- buttress farms require the consumption of ready-mixed concrete and metal, which increases the cost of construction;
- wooden shields flood the soil of the backfill, which worsens the work of the structure as a whole;
- to compensate for the holding moment, plantar bars are installed between the frames, which requires additional consumption of reinforced concrete;
- significant flattening of the construction of buttress farms along the section of the structure;
- the design does not stipulate the deepening of its plantar beams to the erosion depth;
- high costs of reinforced concrete - 3 m ³ per linear meter;
- the construction is limited in its application and cannot be used for deeper water bodies, as it in this case will require even larger overall dimensions.

 The purpose of the invention is to reduce the volume and terms of construction, increase the economy, versatility and reliability of the structure through the use of prefabricated frame-film or conventional split facing plates.

This goal is achieved by the fact that the proposed structure is equipped with trapezoidal front, lower, rear bars, embedded parts and is made of facing plates of a rectangular or square frame in plan with rigidly sealed around the perimeter in each frame film-shaped polymer reinforced materials placed along the slots made on slope, and the plates are made adjacent to each other along the length of the structure, supported and rigidly fixed to the front trapezoidal beams of the buttress frames, and m I am waiting for myself through anchor ties and embedded parts along the tops of each of the adjacent plates and in the middle part along their length, while the front trapezoidal bars are rigidly fastened with the same lower and rear bars with connecting ties with the mates of the bars to each other with their end edges on the side of their narrowed trapezoidal faces and form on each buttress row in the section of the structure successively mounted in a vertical plane and adjacent to each other with the end edges of the broadened faces of the mates of the lower and rear bars, buttress frames with the orientation of the front beams of the frames and facing plates in the plane of the slope, and the buttress frames adjacent to the base of the lower row are buried to an indelible depth - h _p below the low water horizon, and the lower bars are adjoined by paired broadened faces and each row of buttress frames is mounted in slots cut slope at a distance equal to the length of the facing plates, in addition, the joints between the plates are sealed with concrete, and the slots with them installed the ontrush frames are filled with local or drainage soil, while the polymeric materials rigidly embedded in the frame are mounted along the perimeter in rectangular or square trapezoidal grooves in the cross section of the plates, the descending edges of the grooves being directed towards the polymeric materials, and the grooves are filled with concrete, and the facing plates are inclined in a vertical plane at an acute angle, in addition to the specified, for each buttress row along the section of the structure, the contours are mounted and rigidly fixed to the front beams frame frames, guiding patch beams of T-section, holding the end parts of enclosing frame-film or split plates with their shelves, supported on the broadened front faces of the bars of the buttress frames, while the guide beams and front bars of the buttress frames are fastened by means of anchor ties, and when placing the frames on tight or rocky bases, the lower beam of the lower frame is fixed to the rocky base on the anchors, and for weak bases - the lower frame is buried in the base of the structure, in addition, split pl you made profiled with a wave-like outline of the lower faces except for their supporting parts, in turn, beams buttress the frames are made of recycled, rejected, or new concrete sleepers.

 A comparative analysis of this technical solution with the prototype shows that it differs from the prototype in that the buttress triangular frames according to the proposed solution are made in each row in the section of the structure sequentially mounted, with at least two, and each with a smaller perimeter area, mating with their peaks at the front bars, while the front bars of the buttress frames are located in the plane of the slope, and the frames are placed in the slots with their vertical installation on races Toyan equal to the length of enclosing plates.

 Separate implementation of buttress frames does not require special means for the delivery and installation of the latter, i.e. simplifies their delivery and installation. The implementation of counter-front frames from the same type of beams ensures the simplicity of their assembly at the facility and does not require complex formwork for their manufacture, monolithic concrete and reinforcement, given that the frame beams are made of recycled, rejected or new reinforced concrete sleepers.

 The profiled shape of the trapezoidal cross-section of reinforced concrete sleepers used as beams involves a significant resistance to the soil in the calculation of the stability of the structure. Placing the lower frames and plates below the horizon of low-water waters does not require the installation of an anti-erosion tooth, since they themselves will fulfill this role with lower cost costs. Cladding plates made in the form of rectangular or square frames with a covering layer of polymer reinforced materials and cladding plates pinched around the perimeter of each frame reduce the cost of the structure by reducing the consumption of reinforced concrete.

 In the embodiment, when using the design to strengthen the banks of slopes, slopes, slopes, and also as retaining retaining walls, the design of separate buttress frames does not require the execution of deep slots, which are practically impossible without fixing them, which reduces the cost of construction and requires 4 times their depth less than the prototype, on the other hand, the placement of the prototype frames at a distance of up to 2 meters and the installation of plantar bars requires the development of soil for the entire length of the buttress, which increases It excavates dozens of times in comparison with the cuts of the proposed solution, where the need for their development and filling is negligible.

 Cladding plates, fixed to the front beams of frames by means of guiding beams, reduce costs compared to traditional methods of protecting slopes, slopes, slopes with retaining walls, while the beams not only hold the plates, but also distribute the ground pressure along the height of the structure, ensuring a uniform operation facilities in general.

 The implementation of the guide beam of the T-section increases its rigidity when calculated for bending.

 Placing the lower frames on a dense (rocky) base and sealed with anchors in the rocky soil increases the rollover stability and does not require the development of foundation soil, and with weak bases, recessed lower frames and plates to a predetermined depth pinch the structure with passive soil repulsion along the front of the wall, in this case, paired bars along the lower frame of each row increase the shear resistance due to the profiled surface, and finally, the inclination of the facing plates to the vertical forms an acute angle, due to inventive active earth pressure value, the presence of coupling and angle of internal friction, seismic loads and temporary movable load on top of the proposed structures.

 In turn, the grooves in the slabs made of trapezoidal outlines of the descending side faces towards the polymeric materials provide reliable pinching of the end seal of the latter, taking into account the concrete in the grooves. With significant active pressure, the use of conventional cladding plates due to weight increases the stability of the structure, and a wavy bottom surface increases resistance to displacement.

 Comparison of the proposed technical solution with the prototype made it possible to establish compliance with the criterion of "novelty."

 In the study of other well-known technical solutions in this technical field, the features that distinguish the invention from the prototype were not identified and therefore they provide the proposed solution with the criterion of "Significant differences".

 In FIG. 1 shows a shore protection structure, side view; figure 2 - sloping and retaining structures on a solid foundation, side view; figure 3 is the same, on weak grounds; figure 4 is a variant of the shore protection structure, side view; figure 5 is a view aa in figure 1,2,3,4; Fig.6 is a section bB in Fig.5; in Fig.7 is a section CC in Fig.5; in Fig.8 is a view of DD in Fig.1,2,3,4; Fig.9 is a section EE in Fig.8; figure 10 is a section GG in figure 8 (option); Fig.11 is a section CC in Fig.8 (option).

 The coastal protection, slope reinforcement and retaining retaining structure comprises: facing panels 1.1 'of a rectangular or square frame with rigidly embedded in each of the frames 2 film reinforced polymeric materials 3 along their perimeter, moreover, the panels 1.1', dialed into cards adjacent to each other to a friend along the length of the structure, they are supported and rigidly fixed both to the front profiled trapezoidal beams of 4 buttress frames 5.5 'and to each other, by means of anchor ties 6 and embedded parts 7 along the tops 8 of each adjacent it 1.1 'and in the middle part along their length, in turn, the face profiled trapezoidal bars 4 are rigidly fastened with the same lower 9 and rear 10 bars connecting links 11 with the mating bars 4,9,10 to each other with their end ribs 12 from the side their narrowed 13 faces, forming along each buttress row 14 in the section of the structure, successively mounted one after the other in the vertical plane and adjoining each other with end edges 15 of the plantar widened faces 16 of the mating lower 9 and rear 10 parallel bars of the counter clear small triangular frames 5.5 'with the orientation of the front beams 4 frames 5.5' in the plane of slope 17 and facing plates 1.1 ', in addition to the indicated, the lower buttress frames 5' of each row 14 are recessed to indelible depth - hp below the GMV- horizon of low-water waters with lining plates 1 'mounted on them, while the lower bars 9 are made of paired 18 broadened 16 faces, and finally, each row of 14 buttress frames 5.5' is mounted in slot 19 along slope 17 at a given distance equal to the length of the facing 1.1 'slabs, nodes at the vertices of 8 each adjacent slabs 1,1 'in the places of their hard termination with embedded parts 7 are sealed with concrete 20, and the slots 19 are filled with local go drainage soil 21 as the buttress frames 5.5' are installed. In a variant embodiment of the device of enclosing structures for strengthening slopes, slopes, slopes and retaining walls for each buttress row 14, they are mounted along the section of the structure and rigidly fixed to the front 4 bars of the buttress frames 5.5 'guide beams 22 of T-section, holding their shelves 23 frame 2 of 1.1, enclosing plates resting on front beams 4 with broadened faces 16 of 5.5 контр buttress frames, while the inclined guide beams 22 and front beams 4 of 5.5 контр buttress frames are fastened with 24 anchors, count The number of buttress frames 5.5 'in row 14 along the cross section of the structure is at least two, while with dense (rocky) bases 25, the lower beam 26 of the lower frame 5' is fixed to the rocky base 25 on anchors 27, and with weak bases 25 'the lower the frame 5 ′ is sunk into the base 25 ′ to a predetermined depth, similar to the above shore protection structure, the buttress frames 5.5 ′ being made of recycled, rejected or new reinforced concrete sleepers.

 In turn, the rectangular frames 2 of the facing slabs 1,1 'contain trapezoidal grooves 28 along the perimeter with the descending side faces 29 towards the polymer reinforced material 3 and concrete grouting 30 of the latter, in addition, the facing slabs 1,1', as an option when protecting slopes , slopes, slopes and retaining walls are made of conventional split plates 31 with a profiled undulating bottom face 32, excluding supporting parts.

Bank protection, slope and retaining structure works as follows:
1. The work of the shore protection structure.

 When the GMB is a low-water horizon, the shore protection structure made of frame rectangular or square plates 1.1 ', perceiving the load from the mobile transport and the pressure falling on the rear bars 10 frames 5.5' for each buttress row 14, seeks to bring them out of equilibrium due to the overturning moment around the lower part of the frame panels 1,1 ', buried below the GMW - the low water horizon, by indelible depth hp, and also to shift them horizontally towards the aquatic environment, however the frame plates 1,1' are I am in a stable position, given that they are rigidly fixed to the front beams of 4 buttress frames 5.5 ', on anchor connections 6, and the latter are buried in the slot 19 and filled with local or drainage soil 21, thereby ensuring that the holding moment is not only due to their weight, but to an increase in passive resistance along the lateral faces of the lower bars 9 along all buttress rows 14 with buttress frames 5.5 ', and filling the slots 19 with drainage material not only relieves hydrostatic pressure due to a drop in piezometric rivative, but it also increases the resistance to displacement of the soil 21 of the holes 19 with the slope soil, in addition, the rigid connection of the frame plates 1,1 'along their vertices 8 to each other on the embedded parts 7 and the monolithic connection of concrete joints 20 provides the rigidity of the interface nodes as frame plates 1 1 'and 5.5' buttress frames in the places of their joining and their single work with ensuring water tightness in these units.

 In addition to the above, the connecting connections 11 between the bars 4,9,10 provide the rigidity of the buttress frames themselves, in addition, the shore protection structure is stable and in the horizontal plane of the force due to the involvement of passive repulse involved by the rear bars 10 (their side profiled sides), as well as paired bars 18 along the lower bars 9 of the buttress frames 5 due to their profile surface along the base of the frames 5. Active soil pressure attributable to the film reinforced material 3 along the frame plates 5.5 ', lump ensirovano its strength characteristics and tight sealing of the perimeter frame 28 in the grooves 5,5 'concrete 30, the grooves 29 faces downward frames 5,5' provide a wedging polymer material and their concrete grouting 30 and pulls compensation loads.

 In addition to the indicated buttress frames 5.5 ', sequentially mounted in vertical rows 14 one after another in the section of the structure with the orientation of their front beams 4 in the plane of the slope 17, provide a minimum amount of excavation work, both in the development and filling, which reduces the cost and reduces construction periods, in addition, 5.5 'frames made from recycled rejected or new sleepers reduce the cost of production due to their low cost, especially for recycled and rejected sleepers. The assembly of 5.5 'frames from sleepers simplifies installation work, without requiring special lifting and transport vehicles in accordance with the prototype.

The deepening of the lower buttress frames 5 'and the frame plates 1' below the GMW - the horizon of low-water waters to indelible depth - h _p of the same structures, corresponding to the sloping structures of plates 1 and frames 5, reduces the size of the structure, without requiring dissimilar mechanisms, in particular machines driving a dowel-tooth or a massive tooth made of concrete, and also reduces the cost of construction while reducing the mechanical equipment of the facility for the construction of the structure.

 To compensate for shear forces with dense (rocky) bases 25 below the lower buttress frames 5 ', the latter are fixed on anchors 26 to a dense base 25, without requiring the installation of a tooth and paired bars 18, but only the lower beam 9. And finally, the oblique face beams of frames 5.5 'and, respectively, frame plates 1.1' at an acute angle to the vertical, reduces the active pressure of the soil, while increasing the holding moment due to the transfer of the center of gravity towards the coastal slope, while the acute angle is made taking into account seismic forces, temporary P mobile load and characteristics of the compounded soils.

 The construction work to strengthen the slopes, slopes and slopes, as well as retaining and retaining walls.

 Active soil pressure and temporary moving load, acting on the slopes 1,1 'or plates 31, transfers their force with their end parts to the flanges 23 of the T-guide beams 22, however, the latter are in a stable state due to their rigidity achieved by the given section and reinforcement and fixing them to buttresses 5.5 'on the anchor ties 24, which in turn are rigidly sealed in the slots 19 and filled with soil 21.

 In addition to the above, the shelves 23 of the guide beams 22 insure the concrete seal 30 in the grooves 28 of the frames 5.5 ', providing additional reliability sealing polymer materials 3.

 The use of facing slabs 31 conventional split with a profiled bottom face 32 of a wavy shape increases both the weight load of the slope, slope, slope, as well as the soil behind retaining-retaining walls, and its adhesion along the profiled face 32, in addition, the profiling of the plates 31 is performed along the height of the structure with ridges along the length of the plates, with the exception of the places of support of the latter on the front bars 4.

Using the proposed technical solution will allow:
- reduce the need for reinforced concrete by more than 2 times;
- use instead of ready-mixed concrete on buttress frames, recycled, rejected sleepers, which prolongs their service life and reduces the need for concrete;
- get buttress frames involving passive resistance of the soil, which positively affects the stability of the structure, and therefore the reliable operation of the frames;
- buttress rows from frames do not require continuous excavation and subsequent dumping of slopes, which takes place according to the prototype, frames mounted in slots reduce the construction time, and the arrangement of slots and their filling in volume is negligible in comparison with the prototype, which reduces the cost of construction;
- frames of the same type of bars assembled at the facility do not require special means for delivering the latter to the facility, i.e. simplifies the process of their transportation;
- the installation process of buttress frames is simplified due to their small area in comparison with prototype truss frames, while eliminating the need for special screens for their installation;
- the use of bars made of reinforced concrete sleepers eliminates the need for special cements in an aggressive soil environment, given that the sleepers themselves (their components) are adapted to work in an aggressive environment;
- the use of beams of buttress frames in the form of sleepers, stuffed with prestressed reinforcement, has a positive effect on the complex work of the structure with alternating loads;
- the use of a frame prefabricated design of cladding plates requires the use of small-scale mechanization, and the coating polymer material provides concrete savings;
- deepening the lower frame with the lower plates below the horizon of low-water to the erosion depth does not require a special massive tooth or tooth from piles, which reduces the cost of materials, i.e. provides the cost-effectiveness of the design and its reliability in operation.

 According to the variant of using the design to protect coasts, slopes, slopes, slopes and as retaining and retaining walls.

- the use of guiding beams of the T-shaped outline provides both the rigidity of embossing of facing plates and buttress frames, and the distribution of active pressure along its length;
- allows you to get a lightweight design of the retaining walls, in comparison with traditional known massive walls, with minimal material and labor costs;
- to achieve the versatility of the structure, allowing its use with an extended scope;
- to eliminate emergency places in a short time and increase traffic safety;
- the design enables the installation of plates without welding and monopolizing nodes when mating plates and frames, i.e. simplifies the assembly process of the structure;
- guiding beams with their shelves enhance the compensation of pulling loads for embedding reinforced materials in the grooves of frame plates by clamping an equal plate to the shelf of the guiding beam;
- the use of continuous split cladding plates in structures for strengthening slopes, slopes, slopes and retaining structures with a profiled lower edge not only increases the stability of the structure from their weight load, but also improves adhesion to the ground.

Claims (4)

 WATERPROOF, DISABLED AND SUBSTITUTION-RETAINING STRUCTURE SKIN Yu P, KADUKIN V I, AZAR A AND. 1. Coastal protection, slope and retaining-retaining structure, including buttress frames made in cross section in the form of an equilateral triangle with reinforced concrete slabs fixed to the front surface of the frames, characterized in that, in order to reduce the volume and time of construction, increase efficiency, versatility and reliability in the operation of the structure due to the use of prefabricated frame-film or split facing plates, it is equipped with trapezoidal front, lower, rear bars, zak hellish details and made of facing plates of a rectangular or square frame in plan with rigidly sealed around the perimeter in each frame film-reinforced polymer polymer materials placed along slots made on the slope, the plates being made adjacent to one another along the length of the structure, supported and rigidly fixed both to the front trapezoidal beams of buttress frames, and among themselves by means of anchor ties and embedded parts along the tops of each of the adjacent plates and in the middle part along their length, with the front trapezoidal beams are rigidly fixed to the lower and rear beams of the same type by connecting links with the beams being joined to each other by their end ribs from the side of their narrowed trapezoidal faces and form, along each buttress row in the section of the structure, sequentially mounted in the vertical plane and adjoining one another to the other broadened faces of the mating lower and rear beams buttress frames with the orientation of the front beams of the frames and facing plates in the plane of the slope, with than the buttress frames adjacent to the base of the lower row are deepened to an indelible depth h _p below the low-water horizon, and the lower bars are adjacent to each other by paired broadened faces and each row of buttress frames is mounted in the slots cut along the slope at a distance equal to the length of the tiles, except Moreover, the joints between the plates are sealed with concrete, and the slots with the buttress frames installed in them are filled with local or draining soil, while the polymer materials are rigidly embedded in the frame The grooves are perimeter in rectangular or square trapezoidal grooves in the cross section of the plates, the descending edges of the grooves being directed towards the polymeric materials, and the grooves are filled with concrete, and the facing plates are inclined to the vertical plane at an acute angle.  2. The construction according to claim 1, characterized in that for each buttress row along the section of the structure, guide beams of T-section are mounted and rigidly attached to the front beams of the buttress frames, holding the end parts of the enclosing frame-film or split frames with their shelves, while the guides beams and front beams of buttress frames are fastened by means of anchor ties; moreover, when placing frames on solid or rocky bases, the lower beam of the lower frame is attached to the rock base on anchors, and with abyh grounds lower frame recessed in the base structure, in addition, the slotted plate formed with an undulating profiled cutout on the bottom faces except for their leg portions.  3. The construction according to claims 1 and 2, characterized in that the bars of the buttress frames are made of recycled, rejected or new reinforced concrete sleepers.

Images