RU2045621C1 - Dividing pile wall - Google Patents

Abstract

FIELD: civil engineering. SUBSTANCE: dividing pile wall comprises a solid enclosure from metal grooved piles secured in the bearing layer of the ground. Pile wall is disposed between the foundation of the existing building and that of the building under construction, wrapping around the foundation corners of the latter. The pile wall is provided with grooved piles sunk into the ground and spaced along the pile wall. The grooved piles of the wall are interconnected at the top by welded grooved piles and by horizontal tension bars arranged symmetrically with pile axes at a distance of 1/3 of their pitch. The wall height corresponds to the thickness of the compressed layer of the ground. EFFECT: improved design. 3 dwg

Description

 The invention relates to the construction, in particular, to the device of adjacencies of newly constructed buildings to existing ones, in order to exclude the influence of precipitation of the base of the newly constructed building on deformations of the existing one, a dowel wall is arranged at the junction between them at the base.

A known construction of a dowel sheet pile wall constructed in the ground. The dividing sheet pile wall is a concrete wall that cuts the base from the bottom of the foundations to the bearing soil layer and embeds it to a depth sufficient to absorb the negative friction forces arising from the settling soil of the base of the building being erected. The disadvantages of the device are significant consumption of concrete, high complexity and high cost [1]
Closest to the technical nature of the proposed is a dowel groove wall made of metal sheet pile, has a length equal to the depth of the compressible thickness, the strength of soft soils and the depth of embedment into the carrier layer, sufficient to perceive negative friction. The width of the tongue-and-groove wall is equal to the width of the building being erected at the place of extension to the existing one and is provided at the corners of the building with perpendicular protrusions [2] Significant disadvantages of this device are high steel consumption and high cost.

 The objective of the invention is to reduce the consumption of metal labor and increase the efficiency of manufacturing a dividing sheet pile wall.

 The problem is solved due to the fact that in the well-known dividing sheet pile wall, including a solid fence made of metal sheet piles, fixed in the bearing layer of soil and placed between the foundations of the existing and constructed buildings with coverage in the corners of the foundation of the latter, the height of the sheet piling of the wall is taken equal to the active power of the compressible layer of soil the base of the building being built, individual sheet piles are immersed in the bearing soil layer with a step sufficient to absorb the forces of negative friction of the soil along the joint ntovoy wall separate sheet piling wall at the top of rigidly interconnected sheet pile piles and welds, wherein sheet piles are rigidly connected to the adjacent third sheet piling on the sheet pile step by horizontal strands.

 Distinctive features of the proposed technical solution are as follows.

 The first distinguishing feature is that in the proposed technical solution, the height of the sheet piles along the length of the wall is variable, namely, between individual sheet piles immersed in the bearing soil layer, the height of the sheet piles of the wall is equal to the thickness of the compressible layer of the base of the building being erected. In the known technical solution, the height of the sheet piling of the wall is the same along its length and is equal to the power of the weak layers of soil located below the bottom of the foundation, and the value of embedding the sheet pile into the bearing soil layer. As a result, in the proposed solution, the role of the supporting elements is played by individual sheet piles, and the sheet piles of the wall between the piles have a limited height. In the known technical solution, each tongue and groove plays the role of a bearing element and at the same time cuts through the entire thickness of soft soil, where the tongue practically does not work.

 The increase in the bearing capacity of a sheet pile due to its significant immersion in the bearing soil layer, according to the proposed solution, allows to significantly reduce the height of the sheet pile wall in the span between the sheet piles, which leads to a decrease in the metal consumption of the sheet pile and the overall complexity of its immersion, as well as an increase in efficiency.

 The second distinguishing feature is that the dowels in the upper part are interconnected using welds. In the known technical solution, they are not rigidly connected to each other, since each tongue and groove works like a pile. In the proposed solution, the sheet pile wall works as a multi-span beam-wall, based on sheet piles, which must absorb cutting and bending forces arising from the action of negative friction forces of the soil along the sheet pile wall. Thus, the second distinguishing feature is aimed at solving the general problem, namely, the inclusion of part of the sheet pile wall as a beam, which allows you to reduce the height of the sheet pile wall in the span between the sheet piles.

 The third distinguishing feature is related to the fact that the sheet pile is rigidly connected to the sheet piles of the wall at 1/3 of the pitch of the sheet piles with metal bands with welds. In the known technical solution, such bands are absent. As noted earlier, in the proposed technical solution, the sheet pile wall works as a multi-span beam. In the middle of the span, compressive stresses arise between the sheet piles, and tensile stresses arise over the supports (sheet piles). Compressive stresses, as calculations show, are completely perceived by the soil. For the perception of tensile stresses, a rigid connection of the tongue in the upper part above the sheet piles with metal bands is provided. The third distinguishing feature is aimed at solving the general problem of including part of the sheet pile wall into the work as a beam, which allows to reduce the height of the sheet pile wall in the span between the sheet piles and leads to the solution of the problem.

 The author is not aware of technical solutions in which, as a dividing sheet pile wall, a metal sheet pile immersed to the depth of the compressible thickness of the soil is used, and as a supporting element that receives vertical loads from the sheet pile, individual sheet piles are immersed in the bearing layer of the soil, and the wall sheet piles are welded seams and metal bands are combined into a beam-wall, so the distinguishing features are significant.

 In FIG. 1 shows a general view of a dividing sheet pile wall; in FIG. 2 is a section along AA in FIG. 1; in FIG. 3 section BB in FIG. 1.

The dowel wall arranged between the foundation 1 of the existing building and the foundation 2 being erected includes metal dowels of the wall 3, the individual elements of which are rigidly interconnected, deepened from the bottom of the foundation of the existing building to the depth of the compressible thickness of the base H _{from the} building being built and located across the entire width of the structure being erected building extensions in place covering the basement of the building being erected, sheet piles 4, 5 cut through soft ground and embedded in a carrier layer of soil at a depth h 6 _h and pa required increments l _i along the length of the sheet pile wall, defined by the equality of the negative soil friction forces on the sheet pile wall and the bearing capacity of sheet piles 4, the individual sheet piling walls 3 between themselves and with the bung piles 4 rigidly connected on top of the weld seams over a length l _m sufficient for the perception of shearing efforts, and 1/3 of the step between the sheet piles in each direction from them horizontally located cords 7.

The dowel groove wall operates as follows. When transferring the load from the building being erected to the foundation 2, the negative friction of the settling soil within the compressible soil N _{with is} perceived by the sheet piles of the wall 3 and transferred to the sheet piles, cutting through the soft soil 5 and embedded in the supporting soil layer 6. The pitch of the sheet piles l _i at the depth of their embedment h _c in the bearing layer of soil 6 provides immobility of the sheet piling of the wall 3. Welds between the dowels on the length l _w and strands 7 provide the work of the sheet piling as beam walls, and allow perceiving cutting forces and growing dying stresses in the beam-wall.

Let us make an economic comparison of the proposed and well-known technical solutions using an example of a real object. For a residential building being built on the street. Mozhayskaya 24-25 in St. Petersburg and attached to existing residential buildings, "Foundationproekt" developed a design of a dowel sheet, similar to the well-known technical solution. For the dividing sheet pile wall, a Larsen V sheet pile of 14 m length was used, immersed from the bottom of the foundations, cutting a 12 meter thick weak soil and embedded in the bearing soil layer (moraine loam) to a depth of 2 m. The negative friction of the soil along the sheet pile wall is N _t = 103 kN A 2 meter deep groove is sufficient to absorb this force.

Estimate the cost of the dowel sheet according to the invention. We take the height of the sheet piling of the wall equal to the active power of the compressible layer of the base of the building being built, namely 6 m. With a step l _{i, we} immerse individual sheet piles into the bearing soil layer by 6 m. Thus, the total length of the sheet piles will be 18 m. We determine the step l _i .

3,1 м где F_d несущая способность шпунтовой сваи; γ_к коэффициент надежности (см. СНиП 2.02.03).l _i =

3.1 m where F _{d the} bearing capacity of the sheet pile; γ _{to the} coefficient of reliability (see SNiP 2.02.03).

The load-bearing capacity of the sheet pile was found by the calculation method, as for a driven reinforced concrete pile, and only the resistance of the moraine loam of semi-solid consistency was taken into account
F _d = γ _c [γ _cR RA + UΣγ _cf f _i h _i ]
1 x [1 x 5350 x 0.01 + 1.24 xx (97.6 + 102 + 107)] 432.7 kN, where γ _c = 1; γ _cR = 1; γ _cf = 1 coefficients of working conditions;
R = 5350 kPa;
A = 0.01 m ² the cross-sectional area of the tongue;
U = 1.24 m perimeter of the tongue and groove cross section.

 The laboriousness of dipping the sheet pile wall is also significantly reduced due to a significant reduction in the total length of the dipping sheet pile.

 Thus, an example of a specific design convincingly indicates that the dowel groove wall has a lower manufacturing complexity, 2 times less steel consumption and 2 times cheaper than the groove wall of the known construction. Economic indicators of the subject invention increase with increasing power of a weak soil layer.

 In addition, it should be noted that in the Construction Trust No. 20 of St. Petersburg, a crawler-mounted installation for pressing in piles, including a metal sheet piling with a pressing force of 960 kN, was made and is being operated, which allows you to safely perform work near the existing buildings on the installation of sheet pile walls of the proposed design.

Claims (1)

 DIVIDER HOUSING WALL, including a solid fence made of metal sheet piles, fixed in the base layer of the soil and placed between the foundations of the existing and erected buildings with coverage in the corners of the foundation of the latter, characterized in that for fixing the fence it is provided with sheet piles immersed in the ground layer along the ground, located walls in increments, sheet piles in the upper part are interconnected by sheet piles by welding and horizontal strands located 1/3 symmetrically to the axis of the piles aha last, and the wall height is equal to the power of the compressible soil layer.