RU188706U1 - GABION STRUCTURE - Google Patents

Abstract

The utility model relates to the field of construction and can be used to strengthen the slopes, slopes of roads and device interchanges. The technical result achieved during the implementation of the utility model is to expand the arsenal of technical means that increase the stability of the structure from gabions from the action of horizontal forces in height due to the T-shaped gabions joined by stepped side walls and provided with trunks buried in the ground connecting T-shaped gabions over the entire height of a spatially unchanged structure. To achieve a technical result, a gabion structure containing mesh box frames with a filler in the form of a natural stone is proposed, some of which are provided with central trunks placed in separate vertical rows, recessed into the ground, and another part is placed between them, all of which are gabions fastened together . New is the fact that gabions are made with a T-shaped cross-section. Part of the T-shaped gabions (1), forming vertical rows, is worn on the central trunks (3), which are formed of trellised frameworks with filler. In this case, the walls of the T-shaped gabions (1) are connected to the trunk (3) with the help of screeds (4) located in mutually perpendicular directions, the ends of which are fixed in the frames. Intermediate T-shaped gabions (2) are equipped with a diaphragm (5) connecting the front and rear walls. In this case, T-shaped gabions (1), worn on the central trunk, and intermediate T-shaped gabions (2) with the diaphragm (5) are joined in a horizontal row by side stepped walls, fastened with a binding wire (6), in alternate order. 8 il.

Description

The utility model relates to the field of construction and can be used to strengthen the slopes, slopes of roads and device interchanges.

Known gabion high strength, containing a continuous section of a rectangular shape, consisting of metal mail galvanized multi-turn rings with a diameter of 200 to 290 mm, with a breaking load of the ring - not less than 12 tons interconnected horizontally and vertically, forming a rigid duct and then filling it stone material, the base of the gabion can be fixed to the ground by anchors with a diameter of at least 14 mm to a depth of at least 1200 mm. (Patent of the Russian Federation No. 129948 U1, priority date 03/18/2013, publication date 07/10/2013, by Sarkisov Yu.I., RU).

The disadvantages of the well-known analogue are: insufficient holding capacity in case of a ground fall from a slope, high specific cost of a metal mail mesh of multi-turn rings and a grid of galvanized wire adjoining it with smaller cells, as well as insufficient stability on weak soils subject to heaving and perception of action horizontal loads.

Known reinforced construction of gabions, adopted as a prototype, containing box-shaped mesh frames with filler, in which piles are buried in the ground, interconnected by reinforcement ties, separate gabions are mounted on the piles, between which intermediate gabions are mounted, all gabions are fastened together with the help of spirals screwed through the holes of the internetwork cells of the adjacent gabion panels, and steel reinforcing ropes connecting the piles are installed over each row of gabions, on the piles are installed collars from the corner profile, with the help of which the ends of steel reinforcing ropes are fixed between the piles, with the subsequent rows of gabions fastened to the previous ones and with the ropes between them using spirals (Patent RF №181989 U1, priority date 05/17/2018, date of publication 07/31/2018, authors: Presnov, OM and Dolgikh, MV, RU, prototype).

The disadvantages of the prototype are: insufficient provision of bearing capacity, the possible probability of collapse of the upper gabions under the pressure of the soil, as well as the complexity of installation.

The technical problem solved by the utility model is the creation of a reinforced gabion structure, which provides reliable height stability, increased structural protection against possible ground collapses, and low installation labor.

To solve the technical problem, a gabion structure containing mesh box frames with a filler in the form of a natural stone is proposed, some of which are provided with central trunks placed in separate vertical rows, recessed into the ground, and another part is placed between them, all of which are gabions fastened together , characterized in that the gabions are made with a T-shaped cross-section, part of the T-shaped gabions, forming vertical rows, is worn on the central trunks, which are formed lattice frames with filler, while the walls of these T-shaped gabions are connected to the trunk with screeds located in mutually perpendicular directions, the ends of which are fixed in the frames, and the intermediate T-shaped gabions are provided with a diaphragm connecting the front and rear walls, and T -shaped gabions, worn on the central trunk, and intermediate T-shaped gabions with a diaphragm are joined in a horizontal row by side stepped walls, fastened with a knitting wire, in alternate order.

FIG. 1 - a schematic representation of the construction of gabions, a general view; in fig. 2 shows section A-A in FIG. one; in fig. 3 shows a section B-B in FIG. 2; in fig. 4 shows a 3D model of a T-shaped gabion with a central trunk; in fig. 5 shows a scan of an intermediate T-shaped gabion with a diaphragm; in fig. 6 shows a scanning of a T-shaped gabion with holes for a central trunk; in fig. 7 is a schematic representation of a trellised trunk; in fig. 8 - schematically depicted tie.

The inventive gabion design contains mesh box-shaped frames with a filler in the form of a natural stone and with a T-shaped cross section, which are T-shaped gabions 1 and 2. T-shaped gabions 1 are put on central trunks embedded in the ground, which are formed of trellised frameworks with a filler. The walls of the T-shaped gabions 1 are connected to the central trunk 3 using tie rods 4 in mutually perpendicular directions, with the ends of the ties 4 fixed in the walls of the frames of the T-shaped gabions 1 and in the frame of the central trunk 3. Intermediate T-shaped gabions 2 are fitted with a diaphragm 5, connecting the front and rear walls of the T-shaped gabion 2. T-shaped gabions 1, worn on the central trunk, forming vertical rows, and intermediate T-shaped gabions 2 located between them and the diaphragm 5 are joined in a horizontal row Do the side stepped walls, fastened by knitting wire 6, in alternating order, as shown in FIG. 2

Installation of the proposed design of gabions as follows. In the penetrations made in the ground, the lattice frameworks of the trunks 3 are installed, for example, with a diameter of 30 (cm) and a length of 4 (m) in the design position with a step of 5 m, which are filled with natural stone to the ground level. Horizontal and vertical rows are formed from T-shaped gabions 1 and 2 in the form of T-shaped boxes with a length of 3 m, a width and height of 1 m each from a metal mesh frame and core. In this case, T-shaped gabions 1 with holes are formed on trunks 3, and between them T-shaped gabions 2 with diaphragm 5 are installed. When forming T-shaped gabions 1, the walls of their skeletons are connected to the trunk using tie rods 4 in mutually perpendicular directions, the ends of the ties are fixed in the gabion and trunk frameworks. Along with stepped side walls in alternating order, T-shaped gabions 1 and 2 are interconnected by knitting wire. As a result, they form a structure of T-shaped gabions to a certain height and length, obtaining greater stability in the horizontal and vertical directions and providing a spatially immutable system.

Thus, the technical result achieved in the implementation of the utility model is to expand the arsenal of technical means that increase the stability of the structure from gabions from the action of horizontal forces in height due to the T-shaped gabions, joined by stepped side walls and provided with trunks buried in the ground, connecting T-shaped gabions along the entire height of a spatially unchanged structure.

The advantage of the utility model in comparison with the prototype is also the reduction of labor costs during the construction, due to the simplification of the construction of shafts and the exception of energy-intensive operations for the construction of driven piles.

Claims (1)

A gabion structure containing mesh box-shaped frames filled with natural stone, some of which are provided with central trunks placed in separate vertical rows, recessed into the ground, and the other part is placed between them, all of which gabions are bonded to each other, characterized in that The gabions are made with a T-shaped cross-section, a part of the T-shaped gabions, forming vertical rows, is put on the central trunks, which are formed by trellised frameworks with filler, with The walls of these T-shaped gabions are connected to the trunk using tie-rods in mutually perpendicular directions, the ends of which are fixed in frames, and the intermediate T-shaped gabions are fitted with a diaphragm connecting the front and back walls, while the T-shaped gabions worn on the central trunk , and intermediate T-shaped gabions with a diaphragm are joined in a horizontal row by side stepped walls fastened with a knitting wire, in an alternating order.

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