RU2398935C1 - Method for improvement of foundation bearing capacity - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method for improvement of existing foundation bearing capacity includes breaking-off and disassembly of upper variable part of existing foundation, installation and alignment of rigid metal blocks with anchor bolts for new equipment, welding taps of existing foundation to elements of frame of rigid metal blocks, filling cavities of rigid metal blocks with monolithic concrete. Existing foundation is broken-off down to its basement. Existing foundation is enclosed into metal cartridge of angles and fixed with anchor pins, spatial reinforcement frames are welded to angles of metal cartridge and rigid metal blocks, and full weight of foundation with increased bearing capacity is identified using given dependence.

EFFECT: increased bearing capacity, reduced vibration, lower material intensity and labour intensiveness in process of reconstruction.

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Description

The invention relates to construction and can be used to increase the bearing capacity of existing massive foundations during reconstruction, when replacing obsolete equipment with new, more powerful.

There is a method of reinforcing foundations with a reinforced concrete cage in the form of a bell or ring, with the upper part of the foundation being disassembled. Separate foundations are combined into a group. The joint work of new and old concrete is provided by notches along the outer surface of the foundation, by arranging dowels by cutting corresponding grooves in the existing foundation, by welding outlets to existing reinforcement (A.I. Baytsur, L.G. Molchanov. Designing foundations for equipment of industrial enterprises, Kiev, "Alarm Clock", 1977, pp. 166-168).

The disadvantages of this method of strengthening the foundation are the high complexity, due to the need to open and expose the reinforcement of the foundation around the perimeter, the lack of a relationship between the parameters of new and old equipment and foundations, which can determine the total weight of the new foundation, sufficient to dampen the vibration of the newly installed more powerful equipment.

Closest to the proposed method of reinforcing foundations is a method including tearing and disassembling the upper variable part of an existing foundation, installing and aligning rigid metal blocks with anchor bolts for new equipment, welding outlets from the existing foundation to frame elements of rigid metal blocks, filling cavities of rigid metal blocks cast concrete (Recommendations for the design of foundations for technological equipment built in reconstruction, X Arkovsky Design and Research Institute (Promstroiiproekt) Gosstroy USSR, Moscow, Stroyizdat, 1989) (prototype).

The disadvantages of this method of strengthening the foundation are the connection of rigid metal blocks not with the entire volume, but only with the upper part of the existing foundation, the lack of a relationship between the parameters of new and old equipment and foundations, by which it is possible to determine the total weight of the new foundation, sufficient to dampen the vibration of the newly installed more powerful equipment. The problem solved by the invention is to simplify the process of strengthening the foundation for new, more powerful equipment, eliminating vibration of the equipment.

The problem is solved in that in a method of increasing the bearing capacity of an existing foundation, including tearing down and disassembling the upper variable part of an existing foundation, installing and aligning rigid metal blocks with anchor bolts for new equipment, welding outlets from the existing foundation to frame elements of rigid metal blocks, filling cavities of rigid metal blocks with cast concrete, a fragment is made to the base of the foundation, the existing foundation is enclosed in metal th clip from the corners, fixing it thereon anchor pins, to the corners of the metal ring and the metal block is welded rigid spatial reinforcement cages, and the full weight of the foundation with an increased bearing capacity is determined by the ratio

,

,

where R ⁿ , R ^with - the weight of the pumping unit (pump and engine) new and old, kN;

,

- вес роторов двигателей нового и старого, кН;

,

- weight of the rotors of the engines of the new and old, kN;

α ⁿ , α ^s - dynamic coefficient of equipment of the new and old;

,

- расстояние от подошвы фундамента до центра масс насосного агрегата нового и старого, м;

,

- distance from the bottom of the foundation to the center of mass of the pumping unit new and old, m;

ω ⁿ , ω ^s - engine speed;

k - coefficient taking into account the distribution of the load from two pumps to one common foundation;

,

- вес нового и старого фундаментов, кН;

,

- the weight of the new and old foundations, kN;

,

- расстояние до центра масс фундаментов нового и старого, м;

,

- distance to the center of mass of the foundations of the new and old, m;

,

- расстояние от подошвы фундамента до уровня чистого пола, м.

,

- distance from the bottom of the foundation to the level of the clean floor, m

Figure 1 shows a General view of existing and new (reconstructed) foundations with rigid metal blocks.

Figure 2 is a section aa in figure 2 is a cross section along the foundations.

In Fig.3 - section bB in Fig.2 - a metal clip from the corners, framing the existing foundation.

Figure 4 - scheme of pouring concrete foundation.

The implementation of the method of strengthening the foundation is carried out in the following sequence.

After dismantling the equipment, a fragment of the existing foundations 1 (see Figs. 1 and 2) is made to the base and the variable surface layer of the existing foundations 1 is dismantled to the reinforcement 2. Each of the existing foundations 1 is enclosed in a metal clip 3 from the corners from the base of the existing foundations 1 to the mark bare reinforcement 2 (see FIGS. 2 and 3), securing a metal clip around the perimeter of the existing foundation with anchor studs 4. On the exposed reinforcement 2, rigid metal blocks 5 are installed with anchor bolts 6 under the new e equipment. After the alignment, the frame elements of the rigid metal blocks 5 are welded to the outlets of the bare reinforcement 2 and to the metal holder 3. The weight of the new foundation, which excludes vibration of more powerful new equipment, is determined depending on the weight of the equipment of the new and old and the rotors of the electric motors of the new and old, equipment dynamic factors new and old, geometric dimensions of the equipment of the new and old and the foundations, existing and new, in relation to

The weight of the new foundation, the overall dimensions of the new equipment and existing foundations determine the dimensions of the new foundation with a constant depth of existing foundations. Spatial reinforcing frames 7 are welded to the corners of the metal holder 3 and the rigid metal blocks 5. The existing foundations are hydro-sandblasted. Put the formwork 8 around the reinforced spatial frames 7 of the existing foundations 1 and hard metal blocks 5 (see figure 4). The gaps between the formwork 8, rigid metal blocks 5 and the existing foundations 1, reinforced with spatial frames 7, are filled with concrete 10 on a fine aggregate through a tray with a vibrator 9.

The conclusion of existing foundations in a metal clip from the corners allows you to increase its rigidity and bearing capacity.

Fixing anchor pins 4 metal cages 3 on existing foundations 1 allows you to connect the existing foundations and metal cages in one piece, excluding the operation of opening the existing foundations around the perimeter to the reinforcement, which is time-consuming in cramped work conditions.

The installation, followed by welding, of hard metal blocks 5 on metal clips 3 from the corners allows you to distribute the load from the equipment to the entire volume of the foundation.

Using the revealed correlation allows, depending on the weight of equipment and rotors of electric motors, equipment dynamic factors, geometric dimensions of equipment and foundations of existing and new, to determine the weight of a new foundation, excluding vibration of more powerful equipment, as well as its dimensions at the existing depth.

Welding of spatial reinforcing cages to the corners of the metal cage and rigid metal blocks in terms of the volume of the new foundation allows, after pouring concrete, to obtain the foundation that is able to perceive the loads from new equipment as monolithic reinforced concrete throughout the volume.

The method is implemented when replacing two 10D6 pumping units located on two adjacent foundations, with more powerful 14D6.

Characteristics of pumping units Characteristics of pumping units Designation 14D6 10D6 1. The total weight of the pump unit, kN R ⁿ , R ^s 49.43 16.50 2. Weight of the pump, kN 15.15 4,50 3. The weight of the rotor of the electric motor, kN

,

,

20.57 7.20 4. The distance from the bottom of the foundation to the center of mass of the pump unit, m

,

0.635 0.465 5. Frequency of rotation of the electric motor, rad / s ω ⁿ , ω ^s 152.26 152.26 6. The coefficient of proportionality (dynamism) of the equipment α ⁿ , α ^s 0.15 0.15

Characterization of foundations Characterization of foundations Designation 14D6 10D6 1. Depth of the foundation from the level of a clean floor, m 1,350 1,350 2. The distance from the bottom of the foundation to the level of the clean floor, m

,

,

0.400 * 0.150 3. The distance from the bottom of the foundation to the center of mass of the foundations, m

,

0.875 0.750 4. The dimensions of the foundation in terms of grillage (length x width), mm 3000 × 1500 * 2500 × 1200 * Determined by the size of hard metal blocks.

от основания фундамента до отметки плюс 0,050 м оголенной арматуры 2 (см. фиг.2, 3), закрепляя каждую металлическую обойму 3 по периметру существующих фундаментов 1 анкерными шпильками 4 (анкер-гильза HLC 16×140/92 Hilti с контролируемым моментом затяжки) с шагом 700 мм. На оголенную арматуру 2 устанавливают жесткие металлические блоки 5 из двутавров и швеллеров №18 с анкерными болтами 6 под новое оборудование. После выверки элементы каркаса жестких металлических блоков 5 приваривают к выпускам оголенной арматуры 2 и к металлической обойме 3. По выявленной зависимости с учетом габаритов жестких металлических блоков 5 определяют границы и вес нового фундамента, объединяющего существующие фундаменты, исключающего вибрацию более мощного оборудования. К уголкам металлической обоймы 3 и жестким металлическим блокам 5 приваривают пространственные арматурные каркасы 7 из сеток арматурных по ГОСТ23279-85 (AIII, диаметром 12 мм). Гидропескоструят существующие фундаменты. Выставляют опалубку 8 вокруг, армированных пространственными каркасами 7, существующих фундаментов 1 и жестких металлических блоков 5 (см. фиг.4). Через лоток с вибратором 9 заполняют опалубку бетоном В22,5 на мелком заполнителе. Установку насосных агрегатов на новый фундамент производят после набора подливкой 70% прочности, в соответствии с паспортом на оборудование.After dismantling the equipment, a fragment of the existing foundations 1 (see Figs. 1 and 2) is made to the base and the variable surface layer of the foundations is dismantled to reinforcement 2 from the mark plus 0.150 m to plus 0.050 m. Each of the existing foundations is enclosed in a metal cage 3 from the corners

from the base of the foundation to the mark plus 0.050 m of bare reinforcement 2 (see Fig. 2, 3), securing each metal clip 3 along the perimeter of existing foundations 1 with anchor rods 4 (HLC anchor sleeve 16 × 140/92 with controlled tightening torque) with a step of 700 mm. Hard metal blocks 5 of I-beams and channels No. 18 with anchor bolts 6 for new equipment are installed on bare reinforcement 2. After the alignment, the frame elements of the rigid metal blocks 5 are welded to the outlets of the bare reinforcement 2 and to the metal holder 3. According to the revealed dependence, taking into account the dimensions of the rigid metal blocks 5, the boundaries and weight of the new foundation uniting the existing foundations, excluding vibration of more powerful equipment, are determined. To the corners of the metal holder 3 and the rigid metal blocks 5, spatial reinforcing frames 7 of reinforcing meshes are welded in accordance with GOST23279-85 (AIII, diameter 12 mm). Hydro sandblast existing foundations. Put the formwork 8 around, reinforced with spatial frames 7, existing foundations 1 and rigid metal blocks 5 (see figure 4). Through the tray with a vibrator 9 fill the formwork with concrete B22.5 on a fine aggregate. The installation of pumping units on a new foundation is done after a set of 70% strength by gravy, in accordance with the equipment passport.

The foundation, reinforced by the claimed method, perceives weight and dynamic load from two more powerful pump units, dampens vibration and evenly distributes the load on the ground, working as a monolithic reinforced concrete throughout the volume.

The application of the proposed method of strengthening foundations for more powerful equipment will eliminate the long and costly dismantling of the reinforced foundation, the removal of significant amounts of concrete, the use of dangerous gas cutting works (fire) to remove reinforcement (the development of special measures for conducting hot work), save money and, therefore, , reduce the time for reconstruction of foundations and quickly launch new, more powerful equipment into operation.

Claims (1)

A method of increasing the bearing capacity of an existing foundation, including tearing down and disassembling the upper variable part of an existing foundation, installing and aligning rigid metal blocks with anchor bolts for new equipment, welding outlets from the existing foundation to frame elements of rigid metal blocks, filling the cavities of rigid metal blocks with cast concrete, characterized in that a fragment of the existing foundation is produced to the base, the existing foundation is enclosed in metal a boom from the corners, fixing it on it with anchor pins, spatial reinforcing cages are welded to the corners of the metal cage and rigid metal blocks, and the total weight of the foundation with increased bearing capacity is determined by the ratio:

where R ⁿ , R ^with - the weight of the pumping unit (pump and engine) new and old, kN;

,

- weight of the rotors of the engines of the new and old, kN;
α ⁿ , α ^s - dynamic coefficient of equipment of the new and old;

,

- distance from the bottom of the foundation to the center of mass of the pumping unit new and old, m;
ω ⁿ , ω ^s - engine speed;
k is a coefficient taking into account the load distribution from two pumps to one common foundation;

,

- the weight of the new and old foundations, kN;

,

- distance from the base of the foundation to the center of mass of the foundations of the new and old, m;

,

- distance from the bottom of the foundation to the level of the clean floor, m

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