RU2032024C1 - Method for reinforcing the footing of strip foundation during reconstruction of building or structure - Google Patents

Abstract

FIELD: civil engineering. SUBSTANCE: method comprises excavation of trench from external side of foundation. Horizontal parallel reinforcing members are placed into footing with their ends protruding beyond the foundation outline, close to foundation foot at a pitch equal to three times the height of reinforcing member section. Said height of section varies from 0.125 to 0.075 the foundation width and the end portions vary from 0.5 to 1.5 of the foundation width. EFFECT: higher efficiency. 4 dwg

Description

 The invention relates to construction and can be used to strengthen the foundations of strip foundations during the reconstruction of buildings and structures, namely, with their technical re-equipment or superstructure of additional floors, i.e. in case of increased load on the foundation.

 A known method of preventing uneven settlement of building structures on a weak soil base [1]. Vertical trenches are dug in the soil base around the building structure, from which they are subsequently drilled beneath the foundation of the well and horizontal elements are inserted into them (pipes, profile beams, etc.) so that these elements pass under the foundation in the longitudinal and transverse directions, forming a lattice.

 The disadvantage of this method is that it can be used only for individual foundations and it is almost impossible to apply to strengthen the tape foundations. Under the strip foundation, the creation of longitudinal elements is difficult. Drilling wells reduces the bearing capacity of the structure, because it does not allow you to create the necessary zone of compacted soil. In addition, this method requires the use of sophisticated drilling and crushing equipment.

 There is a method of fixing the foundation foundation [2], selected as a prototype, according to which trenches are dug along the structure to be strengthened, then wells are laid in the base with a pneumatic punch, bent like design lines of equal horizontal stresses, which are filled with cement mortar and connected at the ends with jumpers. The distance from the bottom point of the foundation to the top point of the axis of the curved pile should be no more than three diameters of the pile, and the distance between the axes of two parallel piles should be at least six diameters. The junction of piles with jumpers is made with reinforcing elements.

 The disadvantage of this method is the limited application. For example, it cannot be used in soils where the walls of paved wells are being washed or shed.

 The aim of the invention is to expand the scope of the method for soil conditions, increasing productivity by reducing the number of technological operations.

 The proposed method of reinforcing the foundation of the strip foundation during the reconstruction of buildings and structures includes the development of trenches on the outside of the foundation and placement of horizontal reinforcing elements parallel to each other in the base with the formation of their end sections outside the foundation contour. The placement of the elements is carried out using a pneumatic punch close to the base of the foundation with a step equal to three dimensions of the height of the section of the element, and the height of the section of the element is within 0.075-0.125 of the width of the foundation, and the end sections are within 0.5-1.5 of the width of the foundation. The magnitude of the departure of the end sections beyond the boundaries of the foundation is determined by calculation. To increase the strength of the reinforcing elements can be bent.

 In the proposed method, in contrast to the prototype method, the finished reinforcing elements with the help of a pneumatic punch are installed close to the base of the foundation with a step equal to three dimensions of the height of the cross-section of the reinforcing element, and the height of the cross-section of the reinforcing element should be within 0.075-0.125 of the width of the foundation, and the end sections should be within 0 , 5-1.5 widths of the foundation.

 Pneumatic punching of reinforcing elements creates a reinforced soil layer in the base and allows fixing the foundation foundation in any weak soils requiring reinforcement. The location of the reinforcing elements directly below the foundation and the selection of the optimal sizes of the reinforcing elements (height of departure) allows to reduce the number of technological operations due to the one-time driving of horizontal reinforcing elements and the absence of work on the manufacture and reinforcement of jumpers and thus increase productivity and reduce material consumption. In this case, the necessary bearing capacity of the foundation will be provided.

 Figure 1 shows a longitudinal section of a reinforced soil layer; figure 2 is a section aa in figure 1; figure 3 is one of the stages of the method; in FIG. 4 is a diagram for determining the dimensions of reinforcing elements (pipes) with a module of soil deformation E = 5 MPa, for loads P = 0.05; 0.1; 0.15 MPa and the height of the cross-section of the trace elements h = 0.15; 0.2; 0.25 m.

 The method is as follows.

 Pre-determine the size of the trace elements (section height and length). The condition for choosing sizes is the lack of settlement of the foundation after the reconstruction of the building. The calculation is carried out in the following sequence.

For certain soil conditions, a diagram is performed to determine the optimal dimensions of the reinforcing elements. According to the diagram, depending on the existing load on the building P, the initial settlement S _{n of the} building, which occurred under the influence of this load, is determined, the calculated settlement is determined by the formula:
S _p = K x S _n (m), where K is the safety factor, taking into account the inaccuracy of the depth layer.

The point of intersection of the calculated settlement line S _p with the curve corresponding to the selected cross-sectional height of the reinforcing element h and the new load on the foundation corresponds to the required concrete flow rate V per linear meter of the foundation (in case of using pipes as reinforcing elements).

 The intersection point of the concrete flow line V and the height of the cross-section of the reinforcing element h corresponds to the minimum departure f of the end sections of the reinforcing elements outside the basement contour.

 The magnitude of the departure of the end sections of the reinforcing elements beyond the boundaries of the foundation should be within 0.5-1.5 of the width of the foundation. If this condition is not fulfilled, it is necessary to change the height of the element h.

 Having determined the magnitude of the departure of the end sections of the reinforcing element beyond the boundaries of the foundation and, accordingly, the length of the reinforcing elements, make a verification calculation of their strength (the calculation is not given due to fame).

 Near the foundation 1 (at a distance of departure f of the end sections of the reinforcing element), a trench 2 is excavated below the base of the foundation, taking into account the location of the pneumatic punch. A gap is excavated from the trench to the foundation until the depth d of the foundation is precisely determined. An element 3 is placed at the bottom of the trench and clogged with a pneumatic punch 4. Then the remaining elements 3 are driven in the same way. The trench and slot are buried. Thus, a reinforced soil layer is created, which consists of rigid reinforcing elements 3 (pipes, rails of a reinforced concrete structure, etc.) and zone 5 of compacted soil. The distance between the elements 3 cross section height h is 3h. The departure f of the end sections of the reinforcing elements 3 beyond the boundaries of the foundation 1 should be in the range of 0.5-1.5b, where b is the width of the foundation.

 The reinforced soil layer works as follows.

 The load from the foundation 1 is transferred to the rigid elements 3, which together with the sealing zone 5 act on the base, as a result of which the pressure from the structure is distributed over a large area, which leads to a decrease in foundation sediment.

PRI me R. It is necessary to fix the foundation foundation of the building undergoing reconstruction. According to the project, after construction work, pressure on the base should increase from 0.07 to 0.1 MPa. Soft plastic loams l _L = 0.6 and a deformation modulus E = 5 MPa are located at the base. The width of the strip foundation is b = 2 m. Pipes D = 0.15 m (section height) are used as reinforcing elements. Determine the required length of the arm. The condition for calculating the length is the absence of precipitation after reconstruction. The calculation is carried out in the following sequence.

 According to the diagram (figure 4) according to the initial load on the foundation foundation P = 0.07 MPa, we determine the initial settlement that the building had before reconstruction (arrow 1).

S _n = 0.11 m
Determine the estimated settlement of the base.

S _p = K x S _n = 0.85 x 0.11 = 0.09 m
We draw a straight line S _p = 0.09 to the intersection with the curve h = 0.15, corresponding to the load P = 0.1 MPa (arrow 3). Given the selected cross-sectional height of the element h = 0.15 m, in arrow 4 we find the required minimum volume of concrete per linear meter of foundation needed to fill the pipes,
V = 0.165 m / p. m
At the intersection of the lines V = 0.165 m / p. m and h = 0.15 m (arrows 5 and 6) we determine the minimum value of the departure of the end sections of the arm beyond the foundation contour for these conditions (point A) f = 1.1 m, i.e. f = 0.55b (the departure size corresponds to the condition f = 0.5-1.5 b).

We calculate the required length of reinforcing elements
L = b + 2f = 2 + 2 x 1.1 = 4.2 m
The verification calculation of the reinforcing elements showed their sufficient strength (calculation is not given).

Given that the length of the pneumatic punch SO-134A L _p = 2 m, we accept the following process flow diagram for driving elements - pipes: the pipe is clogged in sections, the length of one section L _s = 1.4 m.

Determine the required width of the trench:
b _t = L _c + L _p + 0.5 = 1.4 + 2.0 + 0.5 = 3.9 m
We take the width of the trench b _t = 4.0 m. The calculation is completed. We dig out a trench 4.0 m wide and a gap depth below the base of the foundation 1 by 2h = 2 ˙ 0.15 = 0.3 m. We install the first section of the pipe 6 with the front end closed, hammer it with a pneumatic punch 4. Then we weld the second one to the end of the first section and also hammer, etc. The next row of pipes 6 is hammered at a distance in the axes 3h = 0.45 m. After the introduction of all the pipes under the foundation, we fill them with cement mortar.

 Using the proposed method of securing the strip foundation will increase the bearing capacity of the base in loamy and clay soils from refractory to fluid-plastic consistency and at the same time significantly reduce material and labor costs.

Claims (1)

 METHOD FOR STRENGTHENING THE BASIS OF THE TAPE FOUNDATION DURING RECONSTRUCTION OF BUILDINGS AND STRUCTURES, including the development of a trench on the outside of the foundation and the placement of horizontal arm elements parallel to each other with the formation of their end sections outside the basement contour, characterized in that the arm to the base of the foundation with a step equal to 3 heights of the cross-section of the arm, and the height of the cross-section of the arm is within 0.125 - 0.075 width us basement, and form end portions within 0.5 - 1.5 times the width of the foundation.

Images