RU79896U1 - WATER GRAIN STRUCTURE AS A TWO-TIRE FILTERING BULK WITH A CORFRED PIPE - Google Patents

Abstract

The invention relates to the field of transport construction and can be used as a culvert in embankments, the construction of passages, trunk viaducts, in artificial structures, in rough terrain, as well as when dumping islets and dams in shallow water in all climatic regions of the Russian Federation at an ambient temperature of -50 ° С to + 50 ° С. The culvert in the form of a two-tier structure from the filtering embankment in the lower tier with a corrugated pipe from metal corrugated structures in an armored cage in the upper tier, operating in difficult engineering-geological and seismic conditions. The cross section in the filtering embankment, located on the first tier, depending on the shape of the log and the accepted technology of work, is assigned a rectangular, parabolic, triangular, trapezoidal, which also determines the length of the metal corrugated pipe, and the first tier is poured by the method of free sketching of stone - torn or rounded, fineness up to 0.3 m from frost-resistant non-softening rocks, after backfilling, a reverse filter is placed on top of the filtering first tier, eliminating the leakage of pump soil pi in the cross section of the filtering embankment and its mudding, an embankment of the second tier with a corrugated pipe is poured onto the inverse filter, at the base of which a damping layer is laid in the form of a membrane from a volumetric geogrid with filling the cells with small crushed stone material with a particle size ≤0.02 m, in a holder made of synthetic material. The technical result consists in increasing the reliability, stability, efficiency, the optimal ratio of weight and bearing capacity, time, simplicity and speed of construction, less laborious construction, sufficiently high durability, compliance with environmental protection, efficiency. List of attached documents: Description of the invention - 5 l. Drawings - 8 l., Formula - 1 l.

Description

The invention relates to the field of transport construction and can be used as a culvert in embankments, the construction of crossings, trunk viaducts, in artificial structures, road embankments in rough terrain, as well as when dumping islets and dams in shallow water in all climatic regions of the Russian Federation at ambient temperature air from -50 ° C to + 50 ° C.

As culverts in construction practice during the construction of crossings, trunk viaducts and road embankments in rough terrain, a structure from the embankment layer with a draining layer in the base in the form of a non-woven synthetic material and, located below them, the filtering part in the form placed on top of each other and horizontally are used located plates with vertical channels and with protrusions on their lower surfaces, and the protrusions are oriented in a plan in a checkerboard pattern, and vertical channels located between the protrusions (patent 2059031).

The disadvantage of this structure is its low bearing capacity, the presence of numerous technological operations.

A culvert is known in which the side walls are formed from one row of gabions or Reno mattresses and the foundation located on it in the form of a monolithic grillage. The block of overlap is made in the form of a vault of separate thin-walled reinforced concrete arches, and the bottom part is formed by Reno mattresses or rubble stone (patent 2181812).

The disadvantage of this structure is the need to perform for the arch, separate thin-walled reinforced concrete arches, which complicates the manufacturing technology of these elements, insufficient operational reliability with high seismicity.

Closest to the technical nature of the proposed design is the "Culvert in the armored cage."

The construction includes a pipe made of steel corrugated galvanized structures bent along a given radius, resting on a profiled bed of the base.

The pipe has a damping layer and an enveloping armored casing of layers of reinforced compacted soil of constant thickness of at least 500 mm (patent 2280124).

The main disadvantage is that this structure is not applicable in the presence of frost that can fill the opening of the culvert.

The objective of the present invention is to reduce the material consumption and labor costs for the construction of the structure while ensuring stability, its high adaptability to changing soil, temperature, vibration and seismic resistance, improving the conditions of drainage from water-saturated areas of the body of the embankment in combination with increasing the bearing capacity of its elements - membranes with geogrid, contributing to the redistribution of active forces acting on a moving load, reducing total costs by 20-40%.

The problem is solved due to the fact that the culvert, including a pipe made of metal corrugated structures bent along a given radius and fastened with bolts and nuts with a spherical bearing surface overlapping, resting on a profiled bed of the base in the body of a railway and road bunk embankment, which is made according to the principle collaboration of the filtering embankment located in the first tier and the embankment with a metal corrugated pipe in an armored clip located in the second m tier operating in complex engineering geological and seismic conditions. At the same time, depending on the shape of the log and the accepted technology of work, a cross section of the filtering embankment in the lower tier is assigned - a rectangular, parabolic, triangular, trapezoidal one, which determines the length of the metal corrugated pipe, in the filtering embankment the first tier is poured by the method of free sketching of stone - ragged or rounded, with a grain size of up to 0.3 m, frost-resistant, non-softening rocks, a reverse filter is placed on the top of the sprinkled filtering first tier, eliminating the leakage of soil pi in the cross section of the filtering part of the embankment and its mudding.

An embankment of the second tier is poured onto the inverse filter and a corrugated pipe is installed, at the base of which a damping layer is laid in the form of a membrane from a volumetric geogrid with cell aggregate with small crushed stone material (with particle size ≤0.02 m) in a ferrule of woven synthetic material (such as Geolon ").

The given set of features in comparison with traditional designs provides a technical result, which is expressed in increasing reliability, stability, efficiency, optimal ratio of weight and bearing capacity, time, simplicity and speed of construction, less labor-intensive construction, sufficiently high durability, compliance with environmental protection, economy .

The invention is illustrated by drawings, where:

Figure 1 shows a cross section along the axis 2-2 of the culvert in the form of a two-tier filtering embankment with a corrugated pipe.

Figure 2 shows a cross section along the axis 1-1 of the filtering embankment and the corrugated pipe.

Figure 3 gives the technical characteristics of the volumetric geogrid (for example, "Proudhon 494", where:

on a - a general view of the geogrid in the working (extended) position;

on b - geogrid in transport (folded) position;

on in - a diagram of the connection of tapes forming in spatial position a spatial cellular structure with a given geometric shape and size.

Figure 4 shows the mounting scheme of the geogrid (for example, "Proudhon 494") when laying it at the base of a metal corrugated pipe as a damping layer in the form of a membrane, and also above the casing of the pipe arch, filling the cells with fine crushed stone material (particle size not less than 0 , 02 m), in a holder made of woven synthetic material (such as "Geolon").

Figure 5 shows the waveform of a metal corrugated structure.

Figure 6 shows a diagram of the assembly of pipe sections from links.

Figure 7 shows the connection of two sections of a metal corrugated pipe.

On Fig is given a flow chart of the laying of the reinforcing material and geogrid in the membrane above the arch (casing) and at the base of the pipe.

The culvert 1 includes a filtering embankment and a corrugated pipe:

the first tier is a filtering embankment 2, sprinkled from coarse rocky soil, which is poured onto a notch at the base of the embankment to a depth of at least 1.0 m. A reverse filter 3 is placed on top of the filtering first tier, which prevents the soil from seeping into the cross section of the filtering embankment and its colmatization.

An embankment 4 is poured onto the inverse filter layer by layer, the corrugated pipe 5 is laid on the base of the damping layer 6 in the form of a membrane from a volume geogrid 7 with filling the cells with fine crushed stone material (with particle size ≤0.02 m). An armored ferrule, a protective shell of the pipe, manually sealed by vibratory rammers, are filled with the same material.

A membrane 8 with a volumetric geogrid with cells filling with light gravelly material in a cage made of woven synthetic material (such as "Geolon") is laid over the casing of the arch of a metal corrugated pipe. In front of the inlet head 9 and the outlet head 10, rocky soil of the same granular composition as the filtering embankment is poured to the level of the tray.

From the outlet head along the slope of the embankment, a rocky sketch of 11 is poured with a layer of at least 1.0 m.

Cutting of the topsoil of peat deluvium 12 under the filtering embankment to a depth of 1.0 m

The construction of the culvert is as follows:

the construction site is carefully prepared. Given that at the base of the filtering embankment on most structures in the Russian Federation there are weak peaty soils and in the northern regions frozen soils, the permafrost is often characterized by high ice content, which determines the III-IV category of subsidence with a thawing and freezing depth of 1.1 / 1 , 3 m to

2.5 / 2.7 m, cutting of the upper soil layer under the filtering embankment to a depth of 1.0 m is required with the replacement of rocky soil.

The geometric parameters of the cross section of the filtering embankment 1 are used depending on the calculated flow rate in two ways - with a ratio of the height of the filtering layer in the lower part of the body of the embankment and its width (extension along the railway and highway) 3/10 and 3/20, which allows to determine the proportion the estimated flow rate passing through the filtering mound 2 of the first tier, and through the hole of the metal corrugated pipe 5, designed to pass the remaining flow rate in the second tier.

The stability calculations of embankment 4 are carried out, which determine its geometric contour and, accordingly, the length of pipe 5, taking into account its use at the intersection of deep dens, including those with underground (permafrost) water outlets forming ice with a thickness of up to 1.5 m. Calculations are performed taking into account the joint operation of the pipe 5, located in the second tier of the embankment 4, with a filtering embankment 2, which ensures a non-pressure mode of operation of the pipe with a slope of the tray 0.01, which on steeply falling logs with a slope of the bottom up to 0.33, eliminates the creation of complex water intake structures у at the inlet head 9 (see FIG. 1) and guarantees a smooth flow of the flow through the pipe, which excludes the ice opening of the pipe during the frosty season, which does not have time to melt to the spring flood pass.

The filtration length Lf is equal to the straight length of the cross-section along the base of the embankment, the height of the filter embankment is 3.0 m (structurally accepted).

At the base of the pipe 5, a volumetric geogrid 7 is installed on the sealed layer of the embankment in an extended state with a cell edge height h from 10-200 mm, which is fixed at the corners with anchors from reinforcement AI with a diameter of 10-12 mm and a length of 600-900 mm (see Fig. 3, where 4 is the geogrid section).

The connection of the sections of the geogrids 4 to each other is carried out by steel mounting anchors (4 ′ and 4 ") of a L-shaped or U-shaped type (see figure 4).

The cells of the volumetric geogrid 7 are filled with a gravel-crushed stone mixture with a particle size of ≤0.02 m mechanically directly from dump trucks or a loader to the entire height of the geogrid rib h and is poured over the geogrid ribs by 200-250 mm, then the filling is leveled and aligned, compacted to the level of density not less than 0.95 of the maximum standard, the elimination of excess soil.

The pipe 5 is assembled from metal corrugated structures (see Figs. 6, 7) with a zinc coating, in which the wave of a corrugated sheet of increased strength from 09G2D or 09G2S steel has a sinusoidal shape with a wave step, for example, W _in = 152.4 mm and height h = 50.8 mm with a nominal sheet thickness of 2.5 to 7.0 mm (see figure 5).

Corrugated metal sheets of pipe, bent along the appropriate radius, are delivered to the place of work, where they are assembled in the pipe section using fixing bolts M20x30 and M20x50 of class 8.8, nuts of class 8, washers made of steel of grades 20, 30, 35, which are the place of work is delivered together with corrugated metal structures.

Figure 5 - shows a diagram of the pipe assembly sections of the links (for example, with a diameter of 1500 mm, end view), where the numbers show the order of installation of elements, and - the shift (run) of the longitudinal joints: link A (elements 4, 5, 6) , link B (elements 7, 8, 9).

Figure 7 shows the connection of two sections, where 1, 2, 3 is the installation sequence of the connecting elements; A and B are the ends of the sections; a - shift (run) of the longitudinal joints. The assembly of the elements of the pipe 5 is completely carried out in place and is installed in a protective shell of woven synthetic material (such as "Geolon") on the prepared bed and volume geogrid 7.

To ensure the load-bearing capacity of the pipe at high dynamic load parameters, it is advisable to lay membrane membranes from bulk geogrids dredged from soils of the same nomenclature over the arch (sheath) of the pipe, as the mound 4 in the same sequence as membrane 6 under the metal pipe.

At entrance 9 and output 10 of the pipe head 5, corridor-type openers are arranged, creating smooth flow directions.

Structurally, the openings can be made in the form of volumetric retaining walls made of corrugated metal frame with reinforced primed frozen aggregate.

Claims (5)

1. A culvert, including a pipe made of metal corrugated structures, bent along a given radius and fastened with bolts and nuts with a spherical supporting surface overlapping, resting on a profiled bed of the foundation, characterized in that the culvert in the body of the railway (road) embankment is made in two stages. collaboration of the filtering embankment located in the first tier and the embankment with a metal corrugated pipe in an armored cage located in the second tier se 2. The culvert according to claim 1, characterized in that, depending on the shape of the log and the accepted technology for the production of work, a cross section of the filtering embankment in the lower tier is assigned - rectangular, parabolic, triangular, trapezoidal, which determines the length of the corrugated metal pipe. 3. The culvert according to claim 1, characterized in that the first tier is sprinkled with a free outline of stone - torn or rounded, with a grain size of up to 0.3 m, frost-resistant, non-softened rocks. 4. The culvert according to claim 1, characterized in that a reverse filter is laid on top of the filtering first tier, preventing the embankment from seeping into the cross-section of the filtering part of the embankment and its clogging, and a second tier embankment with a corrugated pipe is poured onto the return filter. 5. The culvert according to claim 1, 4, characterized in that at the base of the corrugated pipe a damping layer is laid in the form of a membrane of a volumetric geogrid with cell aggregate with small crushed stone material (with particle size ≤0.02 m) in a ferrule of woven synthetic material.