RU2211288C2 - Procedure controlling list and sinking of solid mass structure - Google Patents

Abstract

FIELD: construction industry, control over spatial position of structures and constructions listing as result of nonuniform settlement of ground foundations. SUBSTANCE: procedure controlling list and sinking of solid mass structure includes making of through nozzles in solid foundation plate, installation of double-action hydraulic jacks which force loose material into bed under foundation during single cycle by one stroke of hydraulic jacks and return to initial position. Working cycles are continued till bearing capability of foundation exceeds vertical compression effort created by mass of whole structure and foundation of structure begins squeezing out of ground upwards. Characteristic feature of invention consists in making of central and side nozzles expanding downwards and arranged in symmetry around central nozzle in solid foundation plate of structure. Steel anchor ring comprising two semi-rings is inserted into each nozzle, jack beam is placed above nozzle and is tied to anchor ring by anchor bolts. Double-action hydraulic jacks are positioned between foundation beam and each nozzle and their pistons are linked to jack beam. Hydraulic jack is pulled to jack beam by back stroke, nozzles are filled with loose material up to bearing plate of hydraulic jack which outline follows profile of section of inlet of nozzle. Family of double-action hydraulic jacks located in zone of maximal settling of plate of solid mass structure consolidates ground base gradually diminishing list of solid mass structure by synchronous operation. As list of structure diminishes additional families of double-action hydraulic jacks are put in action enlarging consolidation zone of ground base under foot of plate over area. Cycles are repeated till list of solid mass structure is completely corrected while all hydraulic jacks operate over entire area of foot of plate. EFFECT: potential to diminish list of structure with simultaneous provision for operation safety. 3 dwg

Description

 The invention relates to the field of construction, and in particular to the management of the spatial position of building structures and structures that received a roll as a result of uneven settlement of the soil base.

 Closest to the invention is a method of controlling the roll and draft of a massive structure, including performing through nozzles in a massive foundation plate of the structure, installing double-acting hydraulic jacks that in one cycle press the bulk material into the base under the foundation on the stroke of the hydraulic jack piston, and then return to their original position moreover, the process cycles continue until the bearing capacity of the base exceeds the vertical compressive force created by the mass of the entire structure, and the foundation The building component will not start to squeeze up from the ground (see DE 4129995 A1, E 02 D 35/00, 27/34, 03/11/1993).

 The disadvantage of this method is that it is time-consuming and ineffective in hardening the soil base under a massive structure.

 An object of the present invention is to enable roll control of a massive high-rise structure.

 The problem is solved due to the fact that in the method of controlling the roll and draft of a massive structure, including performing through nozzles in a massive foundation plate of a building, installing double-acting hydraulic jacks that press the bulk material into the base under the foundation for one stroke of the hydraulic jack piston in one cycle, and then return to their original position, and the process cycles continue until the bearing capacity of the base exceeds the vertical compressive force created by the mass of the entire structure I, and the foundation of the structure will not begin to be squeezed up from the ground, according to the invention, in the massive base plate of the structure, the central and side expanding downward, symmetrically placed from the central, nozzles are made, a steel anchor ring consisting of two half rings is inserted into each nozzle, a jack is installed over the nozzle beam and connect it to the anchor ring with anchor bolts, and double-acting hydraulic jacks are placed between the foundation beam and each nozzle and their pistons are connected to the jack beam, reverse with a stroke, pull the hydraulic jack to the jack beam, fill the nozzles with bulk material to the hydraulic jack support plate, repeating with its contour the profile of the nozzle inlet section, a group of double-acting hydraulic jacks located in the zone of maximum settlement of the massive structure plate, strengthen the soil base, gradually reduce the heel of the massive structure, acting synchronously with a group of hydraulic jacks, as the roll of the structure decreases, the following additional groups of double-acting hydraulic jacks are connected, increasing the area of hardening of the soil base under the base of the slab over the area, and the cycles continue until the roll of the massive structure is completely eliminated and all hydraulic jacks are included in the work over the entire area of the base of the slab.

 The technical result of the invention lies in the fact that the process of eliminating the roll of a massive structure is mechanized and even automated. Liquidation of the building roll is carried out by one operator from one remote control. In the process of eliminating the roll, the operator receives continuous information from the monitoring group, which determines the amount of the roll and the speed of its removal with the instruments. The operator, using geodetic data on the change in the heel of the structure, includes one or another group of hydraulic jacks, minimizing the heel of the massive structure. Work safety is guaranteed, since at the moment of pushing bulk material under the slabs of the structure, there are no workers in the danger zone. A gradual increase in the strength of the soil base also increases the safety of work. The way to control the roll and draft of a massive structure allows not only to eliminate the existing roll, but also to create a safe roll in the opposite direction. Changing and straightening the heel of the structure can be performed repeatedly.

 The invention is illustrated by drawings, where figure 1 shows a massive structure that received a roll with uneven settlement of the soil base; figure 2 - foundation plate in plan; figure 3 - site installation of hydraulic jacks double action.

 The method is as follows.

 The massive structure has a reinforced concrete or other foundation plate 1, which receives the mass of the structure and distributes the vertical pressure along the entire bottom of the plate 1. In the plate 1, through nozzles 2 are drilled, expanding downward. The upper part of each nozzle is cylindrical, and the lower is conical. In the mating zone of the cylindrical and conical parts, an annular bead is made. A jack cross beam 3 is mounted above the nozzle 2 and supported through the hollow tubular columns 4 on the foundation plate 1. The console of the jack beam 3 is connected by rods 5 to the anchor ring 6. Each of the rods 5 is passed through the console of the jack beam 3, the hollow tubular column 4, through the plate 1 in a special stub in it and through the anchor ring 6. The anchor ring 6 is made for ease of installation of two half rings connected to each other by a bolt connection. The diameter of the cylindrical part of the nozzle 2 is equal to 1.. . 1.2 m, which allows the installer to lower into the nozzle to suspend the anchor ring 6 to the rods 5.

Installation sequence:
- mechanized in the plate 1 drill nozzle 2;
- install columns 4 and a cross-shaped foundation beam 3;
- on temporary supports (not shown), two half rings are lowered into the nozzle 2 and connected to each other in a single anchor ring 6;
- thrust 5 is lowered into the holes in the consoles of the jack beam from above;
- on the lower ends of the rods that have passed through the ring 6, fasten the mounting nuts 7;
- temporary support rings (not shown) are dismantled;
- the nozzle is filled with crushed stone or other bulk material;
- install a double-acting hydraulic jack 8 on the rubble and connect its piston 9 with anchor bolts 10 with the center of the jack beam 3;
- in the same sequence mount the equipment in the remaining nozzles;
- group the hydraulic jacks in groups and each of the groups is connected by an oil line to its pumping station;
- the hydraulic jack control system is displayed on a single remote control;
- in accordance with the roll management program of a massive structure, for example, the Leaning Tower of Pisa, the operator from the control panel includes a group of hydraulic jacks located in the zone of maximum draft of the massive structure slab, and each of the hydraulic jacks of the group presses a portion of crushed stone under one or the other part of massive plate 1, strengthening this is the soil base of this zone under the stove;
- after pressing a next portion of crushed stone under the plate 1, the operator switches on the hydraulic jack return stroke and pulls it to the jack beam 3, freeing up space for the next portion of crushed stone, the cavity is filled with crushed stone, and the next portion of crushed stone is pressed under the plate;
- as hardening of the soil base under the slab, additional hydraulic jacks are included in the work and the zone of hardening of the soil base increases in area;
- the cycles continue until the strength of the soil base under the slab in the zone of its maximum settlement increases to such a value that upon pressing another portion of crushed stone there will be a redistribution of contact interaction stresses between the slab and the ground base and this most settled edge of the slab will begin to be squeezed up;
- controlling the tower roll, continue to squeeze the next portions of crushed stone from the side of the maximum slope of the slab, gradually turning on new hydraulic jacks and preventing the tower from settling from the side of the smallest sloping of the slab;
- The cycles continue until the tower roll is completely eliminated and until all hydraulic jacks are included in the operation over the entire area of the foundation plate;
- controlling the draft and roll of the tower, they continue to squeeze portions of crushed stone with all hydraulic jacks, strengthening the soil base over the entire area of the base plate;
- cycles continue until the sediment of a massive structure begins to decrease and it begins to be squeezed out of the ground;
- in order to attract the flow of tourists, they are forced to give the massive structure a reverse deviation from the original slightly smaller value than it was before;
- turn off the group of hydraulic jacks from the side of the former minimum draft of the foundation plate and, preventing its settlement, turn on the hydraulic jacks from the side of the former maximum draft;
- the cycles continue until the installation of the design roll of the massive structure in the opposite direction from the original and 5 ... 10% less than the original;
- continue to control the roll of a massive structure and, if it grows, adjust the roll as described above.

 An example of a specific implementation.

Длина периметра стен π•d = π•16 = 50,3 м. Принимая толщину стен равной 1 м, объемная масса стен составит 2,4 т/м³. Объем стен равен V=50,3•1•56=2815 м³. Масса стен m≈2815•2,4= 6755,7 т. Массу всей башни принимают в 2 раза большей m≈6755,7•2= 13511,4 т. Управление креном осадкой башни производят двадцатью девятью пятисоттонными гидродомкратами двойного действия. Ориентировочное число домкратов

Домкраты распределяют по площади фундаментной плиты в соответствии с нагрузками на плиту, то есть в основном по контуру плиты (фиг.2). В первую группу объединяют 9 гидродомкратов со стороны максимальной осадки плиты. Во вторую центральную группу объединяют 5 гидродомкратов, находящихся справа от центрального. В третью группу - 5 гидродомкратов, находящихся слева от центрального. В четвертую группу - 9 гидродомкратов, находящихся в зоне минимальной осадки плиты.Let it be necessary to control the roll and draft of the Leaning Tower of Pisa. It is known that the Leaning Tower of Pisa was built over 900 years ago. The height of the tower is 56 m. Already at the beginning of construction, the tower began to unevenly settle and at present its deviation from the vertical reaches a huge value - 4.5 m, that is, the tower has a roll from the vertical equal to α = 4.6 ^o . The same foundation roll. Taking the diameter of the tower d = 16 m, the area of the foundation slab will be

The length of the perimeter of the walls is π • d = π • 16 = 50.3 m. Assuming the wall thickness is 1 m, the bulk density of the walls will be 2.4 t / m ³ . The volume of the walls is V = 50.3 • 1 • 56 = 2815 m ³ . The mass of the walls is m≈2815 • 2.4 = 6755.7 tons. The mass of the entire tower is taken to be 2 times larger m≈6755.7 • 2 = 13511.4 tons. Twenty-nine five-hundred double-acting hydraulic jacks control the heel of the tower draft. Estimated number of jacks

The jacks are distributed over the area of the foundation plate in accordance with the loads on the plate, that is, mainly along the contour of the plate (figure 2). The first group includes 9 hydraulic jacks on the side of the maximum draft of the plate. The second central group combines 5 hydraulic jacks located to the right of the central one. In the third group - 5 hydraulic jacks located to the left of the central one. In the fourth group - 9 hydraulic jacks located in the zone of minimum draft of the plate.

The sequence of preparatory work for the management of the roll and draft of a massive structure
When performing work, they constantly monitor the roll of the structure and the draft of benchmarks installed along the contour of the structure. Drilling of wells and installation of hydraulic jacks starts from the side of maximum draft in turn. After equipping the first nozzle with all the elements, the nozzle is covered with rubble and the initial compression of the rubble is performed to exclude the occurrence of an additional roll of the structure during work. After the installation of hydraulic jacks of the first group is completed, additional crushed stone is compressed with jacks of this group to increase the safety of work. Drill and equip the nozzles of the second and third central groups of hydraulic jacks. Jacks in nozzles are included in the work sequentially in the second and third groups symmetrically with respect to the center. After equipping the next nozzle and filling it with crushed stone, a preliminary compression of the crushed stone with a jack is carried out to increase the safety of work.

 After the work of all the jacks of the second and third groups is completed, additional crushed stone is compressed by jacks of the central groups. Lastly, the fourth group nozzles are drilled and equipped.

 Thus, the preliminary work is completed and on the appointed day after the gathering of tourists align the tower roll.

Hardening the soil base and reducing the tower roll to zero
Hardening of the soil base is carried out primarily from the side of maximum settlement of the foundation slab of the structure, that is, jacks of the first group.

 During the operation of the jacks of the first group, not only some straightening of the tower roll is possible, but also the occurrence of the roll to the right or left. The right roll is achieved by turning on the second right group of jacks, to the left - the third left group of jacks. The simultaneous inclusion in the work of the left (third) and right (second) groups of jacks allows you to strengthen the soil base on the left and right. During hardening of the soil base from the side of maximum slab upset, additional subsidence of the part of the slab where precipitation is minimal (the fourth group of jacks) may occur. Such precipitation is permissible, since they contribute to the elimination of the heel of the entire structure. As the heel of the structure decreases to zero, the fourth group of jacks is included, preventing the foundation plate of the structure from settling in relation to the initial one. Therefore, the alignment of the building roll occurs due to the rotation of the base plate 1 around the χ axis, drawn along the edge of the plate from the side of minimal precipitation (figure 2).

 After reducing the heel of the structure to zero, hydraulic jacks of the fourth group are put into operation and the soil base is strengthened in the zone of minimal precipitation. Hardening of the soil is carried out until the minimum roll towards the former maximum roll, which indicates a complete restoration of the strength of the soil base over the entire area of the base plate.

Creating an artificial roll of the structure in the opposite direction
You can create a roll back of the structure to attract tourists. For stability and reliable operation of the structure, the backward roll should be less than the initial one. The deviation of the tower from the vertical should be 3 ... 3.5 m, which is less than the existing (4.5 m), and is 3..3.6 ^o , which is less than the existing 4.6 ^o .

 To create a backward roll, the structures include the first and central groups of jacks. The central group of jacks squeezes a portion of crushed stone under the foundation plate in volume two times less than the first group. The fourth group of jacks is included in the work only if the draft of this zone increases.

 Thus, after completion of the work, the bearing capacity of the foundation will be fully restored and an artificial roll of the structure in the opposite direction will be created to attract tourists.

 The height of the tower increases by about 1.2 ... 1.3 m.

 If necessary, the tower can be squeezed out of the ground additionally.

 The economic effect of the developed method is the exclusion of the collapse of a historical monument or an expensive massive structure.

Claims (1)

 A method of controlling the roll and draft of a massive structure, including performing through nozzles in a massive foundation plate of the structure, installing double-acting hydraulic jacks that press the bulk material into the base under the foundation for the hydraulic jack piston during one cycle, and then return to their original position, and the process cycles continue until the bearing capacity of the base exceeds the vertical compressive force created by the mass of the entire structure, and the foundation of the structure begins to extrude upward from the ground, characterized in that in the massive slab of the foundation of the building, central and lateral expanding downward, symmetrically placed from the central nozzle, are inserted into each nozzle, a steel anchor ring consisting of two half rings, a jack beam is installed over the nozzle and connected to the anchor ring with anchor bolts, and double-acting hydraulic jacks are placed between the foundation beam and each nozzle and their pistons are connected to the jack beam, and the hydraulic jack is pulled back to the jack b Then, fill the nozzles with bulk material to the base plate of the hydraulic jack, repeating with its contour the profile of the nozzle inlet section, a group of double-acting hydraulic jacks located in the zone of maximum settlement of the massive structure plate, strengthen the soil base, gradually reduce the roll of the massive structure, acting simultaneously with the group of hydraulic jacks, as reducing the roll of the structure connect the following additional groups of double-acting hydraulic jacks, increasing the hardening zone of the soil base under the sole of the first plate in terms of area and cycles continue until the complete elimination of the heel of the massive structure and before the inclusion of all hydraulic jacks over the entire area of the bottom of the plate.

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