RU2667163C2 - Combined (pile-slab, pile-belt, pile-columnar) foundation erection method - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to the field of construction, in particular to the buildings foundations arrangement methods. Building on the combined (pile-slab, pile-belt, pile-columnar) foundations erection method using the driven piles includes the “grillage foundation” with holes for the piles passage arrangement on the ground surface and embedded parts for the driving plant subsequent attachment thereto, the structure superstructures erection on the “grillage foundation”, reactive force compensation during the piles driving by the building erected part weight and the piles embedding in the grillage. Piles driving and embedment begins after the building erection to the certain number of floors, when the load on the “grillage foundation” from the erected structures weight will exceed the amount of load necessary to drive one pile, but will not be more than the soil design resistance under the “grillage foundation” sole.EFFECT: technical result consists in increase in the construction reliability, manufacturability, safety margin and cost effectiveness, reducing in the construction time.4 cl, 1 dwg

Description

The invention relates to the field of construction, in particular, to methods for building foundations of buildings.

A number of known methods for the construction of foundations, representing a combination of shallow foundations and pile foundations. For example, in the analogue of the present invention [1: RU No. 2513050 “Method of erecting foundations in seismic regions”], when arranging a combined foundation (pile-plate), a pile field is arranged, a foundation plate is arranged with holes for the passage of pile heads into them, and a foundation plate is erected upper structures of the structure. After settling the slab under the influence of the weight of the unfinished structure, the holes are concreted, fastening the upper ends of the piles to the slab, which coincides with the essential features of the proposed.

In this case, the pile field is arranged until the foundation plate is created, and the holes are concreted when the sediment reaches half the design value.

The disadvantage of this method is the long duration of the zero-cycle work, which increases the overall construction time, since it is necessary to first arrange a pile field, then build a foundation slab, then erect a part of the upper structures, then make monolithic piles and only then continue the construction. Another disadvantage of this method is that in the process of installing a pile field, the foundation soils are already compacted. To assess the degree of compaction is very difficult. Therefore, due to the increase in the deformation modulus from compaction of soils by piles, it is problematic to establish the value of slab settlement by calculation. Thus, the criterion by which the onset of piling is determined ("... after reaching half of the estimated draft ...") seems very uncertain.

The closest analogue (prototype) of the proposed method is the method [2: Korolev M.V., Guterman M.S., Skrylev G.E., Sazhin D.V. “Effective ways to strengthen foundations in the reconstruction of buildings and structures” // Sat. Proceedings of Moscow State University of Civil Engineering "Modern methods of engineering surveys in construction." Ed. Telichenko VI, Moscow, 2003, S.253-264], in which the existing shallow foundation is supplemented with a reinforced concrete grill with holes for passing piles and embedded parts for subsequent fastening of the crushing installation to them, which coincides with the essential features of the proposed .

In addition, special indentations are arranged in the foundation at the location of the grillage, and the grillage is additionally fastened to the foundation body with anchors. After this, the piles are immersed with a static load using a loading device (power cylinders) and the upper end of the submerged piles is fixed in the grill.

The disadvantage of this method is that it is used only to strengthen the foundations of already constructed buildings, which underwent significant non-uniform precipitation during operation. For new construction, this method does not apply. It should be especially noted that in the prototype of the invention, initially the width of the foundations is designed in such a way that the shallow foundation can absorb the entire load of the building. In the proposed method, the shallow foundation is designed in advance so that it can only accept part of the load from an unfinished building, and the rest of the load from subsequent floors should be perceived by crushed piles, which is a very significant difference. In addition, since the actual load-bearing capacity of each crushed pile can be judged by the force of immersion of piles, this improves the efficiency and reliability of the foundation.

A positive result of the invention consists in increasing the reliability, manufacturability, cost-effectiveness of construction and reducing construction time.

List of drawing figures:

FIG. 1. The implementation scheme of the proposed method.

In FIG. 1 shows the stages of implementation of the proposed method, where the notation is used:

1 - walls of the building; 2 - overlap; 3 - technological holes for passing piles; 4 - foundation of shallow laying (subsequently being a grillage); 5 - submersible piles; 6 - monolithic pile heads.

The various phases of the structure are represented by fragments A, B and C of the drawing:

A) Building a building to the estimated number of floors in such a way that the pressure under the sole of the foundation does not exceed the design resistance of the soil, and the total weight of the structure allows for the immersion of one pile. Installation of piles in technological windows.

B) Immersion of piles using an inventory installation.

C) After immersion of piles to the design depth of monolithic pile heads in holes of shallow foundations (grillages).

In order to overcome these drawbacks, we propose a method of erecting a combined foundation, including a “foundation-grill” device on the soil surface with holes for passing piles and embedded parts for subsequent fastening of the crushing installation to them, erection of the upper structures of the structure on the “foundation-grill”, reactive force when crushing piles, compensate for the weight of the erected part of the building, piles are monolithic in the grillage, characterized in that the crushing and monolithing of piles begins, when, during the construction of the upper structures of the structure, the load on the “foundation-grillage” from the weight of the structures will exceed the load required to crush one pile, but will be less than the calculated soil resistance under the sole of the “foundation-grillage”.

In addition, in the ceilings of lower floors, the total height of which from the ground surface does not exceed the length of the whole crushed pile by more than one storey floor height, open holes located above the holes in the body of the "foundation-grillage", in which the piles are brought in before the next floor .

In addition, during the construction of the upper structures, the amount of precipitation is fixed in various places of the “foundation-grillage” and, first, the piles are crushed and monolithic in those places where the largest precipitation was recorded during the construction of the upper structures, and in the places where the smallest settlement was recorded, piles are crushed and monolithic in the last turn.

In addition, piles immersed in the ground are fixed in the grillage without removing the vertical load acting on them, that is, the piles are monolithic in a “stressed” state.

In addition, since the actual bearing capacity of the piles is judged by the amount of force required to crush it, the pile is immersed until it reaches the required calculated bearing capacity.

The proposed method is as follows.

At the first stage, a shallow foundation is made of precast or monolithic reinforced concrete, in the body of which there are holes for the subsequent passage of piles and embedded parts for mounting the installation for crushing piles into the ground. The depth of the foundation is determined mainly on the basis of the structural features of the building (the presence of the basement). The width of the foundation sole is calculated based on the condition that the pressure under the sole of the weight of the part of the unfinished building height does not exceed the calculated soil resistance. In this case, the load transferred to the building foundation (to the column, or to the running meter of the strip foundation) would be no less than the force required to crush one pile (determined by calculation taking into account the safety factor).

After the foundation is installed, the installation of the upper structures of the building begins to the level (number of floors) so that the above conditions are met, that is, the load on the foundations is in the specified range. The upper structures of the building can be erected both from prefabricated, and from monolithic reinforced concrete or from brickwork. Moreover, to improve manufacturability, it is possible to arrange temporary openings in the lower floors of the building located directly above the “windows” in the foundation, through which piles are passed in advance (Fig. 1).

Next to the embedded parts of the foundation attach the installation for crushing piles, including a movable frame with grips and power hydraulic cylinders.

Then, at the same time, they continue to erect the upper structures of the building and immerse (crush) the piles and monolize them in the grillage. As the piles are crushed and, accordingly, the bearing capacity of the foundations increases, the building can be erected to the design number of floors. It should be noted that crushed piles are monolithic in the grillage in the “stressed” state, for which the vertical load is not removed until monolithic piles in the grillage. In addition, in the process of immersing piles, the crushing force is fixed and the piles continue to be immersed until the crushing force exceeds the required design force on the pile.

It should be noted that the shallow foundation with holes for passing piles performs a threefold function. First, before the construction of a part of the building in height, it works as a shallow foundation (function 1), at the moment of immersion of the piles, the foundation-grillage performs the function of loading, providing the perception of reactive force from crushing the piles due to the weight of the structures erected by this time (function 2 ) After the device and monolithic piles, this structural element performs the function of grillage (function 3). This allows us to increase the manufacturability and reliability of the structure compared to the prototype, where a concrete grillage does not fulfill the function of a shallow foundation (that is, it does not fulfill function 1), but is only a grillage and an element that receives the reactive force from crushing piles (that is, it only functions 2 and 3).

The fact that the holes in the foundation and embedded parts are arranged in advance, and above the holes in the ceilings of the lower floors, temporary windows are also arranged in advance for passing piles, which, after they are crushed, are closed up, increases the manufacturability of building construction, since it is possible to submerge piles not in sections, but over their entire length.

The fact that the beginning of the process of crushing piles and the end of the device of the pile foundation is determined by special ratios (so that the weight of the erected structure exceeds the crushing force of one pile and does not exceed the bearing capacity of the "temporary" foundation of shallow laying), it allows, at the same time, after building the building to the required number of floors, arrangement of the pile foundation and further construction of the upper structures, which, accordingly, reduces the construction time and its cost.

At the same time, the reliability of the structure is simultaneously increased, since more favorable conditions for the work of the foundation are formed, since already at the first stage, before piling, the soil under the foundation is compacted and subsequently the grill takes up part of the total load. The magnitude of this load will be equal to the maximum pressure under the sole of the foundation to the device of piles and even slightly more, since the soil is first compacted when the structure works as a shallow foundation. In the process of crushing piles, the already compacted soil is additionally compacted around the piles. Draft of the building will occur mainly during the construction process and will be very small, corresponding to the load only from part of the structures unfinished in height of the building.

The proposed method can be implemented not only for tape "foundations-grillages", but also for beam, trellised (foundations in the form of cross tapes), columnar and slab foundations. That is, the method can be used for any shallow foundation. The sequence of operations and the conditions for their implementation do not change.

Example:

Let it be required to erect a building with longitudinal bearing walls twenty floors high. Let the weight of the structures of each floor give a load on the foundation of 50 kN per linear meter, and the load, taking into account useful and other loads, be 60 kN per linear meter. Let the calculated soil resistance at the base of the “temporary” shallow foundation be 300 kPa, and the bearing capacity of the crushed pile 300 kN.

To crush one pile, the weight of the building structures must be at least 300 kN per linear meter. That is, the building must be completed to a level of at least six floors (300/50 = 6). In this case, the width of the base of the foundation should not be less than 6⋅50 / 300 = 1 m. The total number of piles located on one running meter of foundations should be at least (60⋅20-300) / 300 = 3. If you accept a foundation 1.5 m wide, then you can start crushing piles after the construction of the sixth floor. Completely the same crushing of piles and the installation of the pile foundation is necessary before the completion of the ninth floor (300⋅1.5 / 50 = 9). Such a foundation will subsequently withstand the full load of the building, taking into account useful and other loads (60⋅20≤300⋅1.5 + 3⋅300).

Note:

The above calculation is approximate and conditional and is given as a simplified illustration of the proposed method. Real calculations are performed in accordance with the requirements of the updated versions of SNiP 2.02.01-83 (SP 22.13330.2011) and SNiP 2.02.03-85 (SP 24.13330.2011).

It should be noted that lower cost and greater reliability are achieved due to the fact that in the process of crushing (by the force of pressing), the bearing capacity of each pile is precisely determined. The share of load perceived by the grillage is more precisely known. In addition, the simultaneous erection of the upper structures and the installation of foundations reduces the time and, consequently, the cost of construction. The proposed method is the most cost-effective under such engineering-geological conditions when relatively low-strength soils occur in the upper part of the base, and the most durable ones occur at a depth of about 5-15 meters.

A greater margin of safety is ensured by the fact that part of the load from the building (and a known part) is perceived by the grillage. The total settlement of the building will be less, since the piles during loading experience a load exceeding the subsequent load from the structure. That is, piles are as if prestressed. The soil around the piles is more compacted, which provides high friction along the lateral surface. Soil under the lower end of the piles during the immersion process is also compacted. In addition, as already mentioned above, a significant part of the load will be perceived by compacted base soils located under the grillage.

In addition, greater reliability is achieved due to the fact that since the installation of the pile foundation is carried out for a certain period of time, it becomes possible to partially smooth out the possible unevenness of the settlement of foundations that manifested itself during construction. To do this, first of all, it is necessary to crush and monolize the piles in those areas that have undergone the greatest rainfall, and in areas with lesser rainfall, this work should be carried out last.

As follows from the above analysis, the required technical result is achieved due to significant differences of the proposed.

Conducted model experiments showed the feasibility of the proposed object of the invention.

Claims (4)

1. A method of erecting a building on combined foundations (pile-slab, pile-tape, pile-columnar) using crushable piles, including a "foundation-grillage" device on the ground surface with holes for passing piles and embedded parts for subsequent mounting to them crushing, erection on the "foundation-grillage" of the upper structures of the structure, compensation of reactive efforts when crushing piles by the weight of the erected part of the building and monoling piles in the grillage, characterized in that the crushing and monolithing of piles begins after the building is erected to a certain number of floors, when the load on the “foundation-grillage” from the weight of the structures being erected exceeds the load required to crush one pile, but will not exceed the calculated soil resistance under the sole “foundation-grillage” ". 2. The method according to p. 1, characterized in that in the ceilings of the lower floors, the total height of which from the ground surface is less than the length of the whole crushed pile less than the height of one floor, arrange holes located above the holes in the body of the "foundation-grillage", which piles start to the next floor. 3. The method according to p. 1, characterized in that the piles are first crushed and monolithic in those places where the greatest precipitation was recorded during the erection of the upper structures, and in the places where the smallest draft was recorded, the piles are crushed and monolized last. 4. The method according to p. 1, characterized in that in the process of immersion of the piles, the crushing force is recorded and the immersion of the piles is carried out until the recorded crushing force exceeds the calculated load on the pile.

Images