RU2221918C2 - Construction method of built-in structural elements in soil - Google Patents

Abstract

FIELD: building equipment. SUBSTANCE: method involves forming well into soil; feeding electrically conducting hardening material into well; placing inventory electric supply having electrodes and connected to impulse electric discharge source into hole; generating high-voltage electrical charges wherein at least one high-voltage electric discharge is carried out with simultaneous feeding of antiknock water containing exothermal mixture in space between electrodes; combusting exothermal mixture by high-voltage explosion with gas, vapor and plasma emission, with pressure increase to 100 MPa and with air blast generation; removing electric supply from hole. Pressure growth and air blast creation result in hole widening, hole wall compaction and hardening material compression. EFFECT: increased soil and hardening material compaction efficiency, possibility of implementation for new buildings construction and for reconstruction or strengthening of existing buildings; extended field of application. 20 cl, 4 dwg

Description

 The invention relates to the field of construction, in particular to methods for erecting printed structures in the ground, including pile foundations, injection anchors, walls in the ground, printed armored structures and other geotechnical structures for various purposes, used both in the construction of new structures and during reconstruction or strengthening existing facilities.

 There is a method of arranging piles with camouflage heel broadening, including drilling a well under a pile, lowering an explosive charge (BB) to the bottom of a well, filling a well with concrete, blasting a detonating charge and forming camouflage broadening in the soil of the lower end of the pile [1]. The disadvantage of this method is the inadmissibility of its use in reconstruction, inside existing facilities because of the danger of an uncontrolled explosion from detonation, etc. The closest to the invention in essence and achievable technical result is a method of erecting a printed structure in the ground, including the formation of a well, filing in a well of hardening material, installation of an inventory electric emitter connected to a source of pulsed electric their discharges, the excitation of high-voltage electric discharges using a radiator, followed by its extraction from the well [2].

 The disadvantage of this method is the low efficiency in most soil conditions due to the inevitable loss of energy in the electric highway and the inability to increase the power of technological equipment in building conditions under the necessary conditions. Known submersible borehole discharge station [3] for processing the walls of oil wells, the disadvantages of which are low energy consumption, which does not allow drastically affect the properties of the soils surrounding the well when used for construction purposes and does not allow to increase the bearing capacity of the system "soil - printed structure in the ground. "

 The objective of the present invention is to increase the effectiveness of compaction of the soil surrounding the printed structure and the material of the structure itself to ensure the compatibility of their work while simultaneously providing the possibility of erecting a printed structure in the soil both during the construction of new structures and during the reconstruction of existing structures or their strengthening, including in close urban development and thereby expand the area of use.

 The problem is solved due to the fact that in the method of erecting a printed structure in the soil, including the formation of a well, supplying a hardening material to the well, installing an inventory electric emitter connected to a source of pulsed electric discharges into the well, exciting high-voltage electric discharges using a radiator with subsequent extraction of it from the well, according to the invention, at least one high-voltage discharge is produced with simultaneous supply to the interelectron The battery emitter knock-free water-filled space exothermic mixture and its combustion at high voltage electrochemical burst with release of gases, vapor and plasma and creating shock waves and pressures up to 100 MPa, further expanding the hole with soil compaction its walls and filling material hardenable well. In this case, as a non-detonating water-filled exothermic mixture, a paste containing aluminum powder, nitrate and water can be used. As hardening material can be used, for example, concrete mix. They can produce uninterrupted electrical discharges. High voltage discharges can produce, at least when the emitter is located on the bottom of the well.

 The emitter can be equipped with a partitioned cartridge for storing and portioning the non-detonating water-filled exothermic mixture during the production of another electrochemical explosion. The emitter can be combined with a submersible discharge power station, which is equipped with a sectioned cartridge for storing and portioning a non-detonating water-filled exothermic mixture, and the station is immersed in the well together with the emitter. After removing the emitter from the well, a reinforcing cage can be immersed in the hardening material.

 Before the emitter is immersed in the well, a reinforcing cage can be attached to it with a detachable connection, and before the emitter is removed, it is disconnected from the reinforcing cage, which is left in the well.

 During the erection of a printed support structure in soils with inclusions of rock, an electric discharge with an electrochemical explosion can be performed with the simultaneous destruction of rock and the formation of an array reinforced with hardening material in the destroyed zone.

 The emitter can be mounted on a hollow rod, and a portion of a non-detonating water-filled exothermic mixture is introduced into the interelectrode space through the rod cavity. A well in the ground can be formed by drilling or using an inventory casing, the extraction of which is carried out cyclically with each cycle before producing another high-voltage discharge or using a thixotropic solution, mainly bentonite, or using an inventory casing with a lost tip, after disconnecting which they are removed casing pipe.

 A pile or an anchor cylindrical or in the form of a truncated cone, facing a large base down or up, or a pile or anchor with at least one broadened section in height, or a wall or enclosing structure from adjacent piles or piles, may be erected in the ground with broadening adjacent to each other, or soil reinforcing structure in the form of piles or anchors with at least one broadened area. In this case, the reinforcing soil structure can be erected in the body of the embankment with the arrangement of piles and / or anchors in rows and / or tiers, respectively, in width and height of the embankment, or the reinforcing soil structure can be erected in bulk soil or natural soil located behind the newly erected or reinforced supporting wall, or wall of the embankment, or the foundation of the bridge, or overpass, or overpass.

 The technical result provided by the given set of features consists in increasing the compaction efficiency of the soil surrounding the printed structure and the material of the structure itself to ensure their joint work and increase the bearing capacity of the "surrounding soil - printed structure in the soil" system while ensuring the possibility of use as in the construction of new structures , and during the reconstruction of existing ones or their strengthening, including in conditions of close urban development and expansion of topics with The most area of use.

The invention is illustrated by drawings, where:
figure 1 schematically shows a well filled with hardening material with a submerged emitter before producing a discharge with the simultaneous supply of a non-detonating water-filled exothermic mixture into the interelectrode space of the emitter;
in FIG. 2 the same, in the case of a breakdown-free discharge with a large interelectrode space and a tubular cartridge with a water-filled exothermic mixture;
in FIG. 3 the same, in the process of treating the surrounding soil with an emitter on a rod for portion feeding of a water-filled exothermic mixture into the interelectrode space of the emitter;
in FIG. 4 the same, with a submersible discharge power station and a cartridge for a water-filled exothermic mixture.

 The method is carried out according to the invention as follows.

 A well-known drilling rig builds a well 2 in the ground 1, cased, if necessary, with an inventory casing 3. Then, fill the well (fully or partially) with hardening material 4, for example, concrete mix. An inventory electric energy emitter 6, connected by the electric main 7 to a source of pulsed electric discharges 8, and a cartridge 10 connected to the electrodes 9 of the emitter 6, filled with a non-detonating water-filled exothermic mixture 11, for example, an aluminum powder paste, are lowered into the calculated location along the depth of the borehole 2 on rod 5; saltpeter and water and located in the interelectrode space 12. At the estimated time of optimal exposure to the hardening material 4, a discharge is produced between the electrodes 9 of the emitter 6. The electrical discharge knock-free water-filled exothermic heats the mixture in the cartridge 10, resulting in high voltage electrochemical explosion and burning of the mixture 11 with the release of a large volume of gas, vapor and plasma. The explosion pressure reaches a value of up to 100 MPa, which forms a vapor-gas cavity in the hardening material 4, which generates a shock wave and hydroflows and pushes the walls of the well 2, sealing the hardening material 4 and the soil 1 surrounding the well 2.

 If it is necessary to carry out a series of explosions, the energy emitter 6 is placed on the hollow rod 5, which allows you to dose the mixture 11 directly into the interelectrode space 12 of the emitter 6.

 To increase the amount of mixture burned and to increase due to this efficiency of the method, it is advisable to apply a break-free discharge mode. This is achieved by diluting the electrodes 9 of the emitter 6 to a distance of 20-250 cm and making the cartridge in the form of a tube 13 filled with a non-detonating water-filled exothermic mixture 11 or introducing a special additive that increases electrical conductivity into the hardening material.

 To increase the strength of the material of the printed support structure, for example, piles 14, the hardening material is treated at a certain time during the hardening of the concrete mixture, in particular, at the time of the violation of the thermodynamic stability of the cementing system [4].

 To improve the quality of compaction of water-saturated sandy soils, it is advisable to treat the wells under excess pressure of the column of hardening material 4, for example, by increasing its level in the casing 3. The emitter 6 can be combined with a submersible discharge electric station 15, which is equipped with a sectionalized cartridge 10 for storage and a batch feed of a non-detonating water-filled exothermic mixture 11 and station 15 are immersed in the well 2 together with the emitter 6, which avoids losses in electric ktromagistrali 7.

 After the emitter 6 is removed from the well 2, a reinforcing cage (not shown in the drawings) can be immersed in the hardening dielectric material or, before the emitter 6 is immersed in the well 2, a detachable connection is attached to it (the reinforcing cage (not shown) is not shown in the drawings, but before the emitter is removed 6 disconnect it from the reinforcing cage, which is left in the well 2.

 During the erection of the printed support structure 14 in soils with inclusions of rock, an electric discharge with an electrochemical explosion is produced with the simultaneous destruction of rock and the formation of an array strengthened by hardening material in the destroyed zone.

 If the well 2 is formed using a casing 3, it can be removed cyclically with each cycle before producing another high-voltage discharge.

 Well 2 can be formed using a thixotropic solution, mainly bentonite, or a pipe with a lost tip (not shown in the drawings), after the connection of which the casing is removed.

 In the ground, a pile 14 or an anchor (not shown) may be erected cylindrical or in the form of a truncated cone, facing a large base down or up, or a pile or anchor with at least one broadened section 16 in height.

 In the ground, a wall or enclosing structure (not shown in the drawings) can be erected from adjacent piles 14 or piles with widenings 16 adjacent to each other.

 A reinforcing soil structure in the form of piles 14 or an anchor with at least one broadened section 16 can be erected in the ground.

 The reinforcing soil structure can be erected in the body of the embankment (not shown in the drawings) with the arrangement of piles and / or anchors in rows and / or tiers, respectively, along the width and height of the embankment.

 The reinforcing soil structure can be erected in bulk soil or natural soil located behind a newly constructed or reinforced retaining wall, or the wall of the embankment, or the foundation of a bridge, or overpass, or overpass (not shown in the drawings).

Sources of information
1. Ganichev I.A. The device of artificial foundations and foundations. - M.: Stroyizdat, 1981, p. 65.

 2. Bakholdin B.V., Dzhantimirov H.A. New electrical discharge technologies in geotechnical construction. Foundations, foundations and soil mechanics. 4, 5, 1998, section "Technology and production of works", p. 47-52.

 3. Kondrikov B.N. Explosive transformations of electrical and chemical energy. - Kiev: Naukova Dumka, 1987.

 4. Garkavi MS. Thermodynamic analysis of structural transformations in hardening systems. "Glass and Ceramics", 1998, 6.

Claims (20)

1. A method of erecting a printed structure in the ground, including forming a well, supplying a hardening material to the well, installing an inventory electric emitter connected to a source of pulsed electric discharges into the well, exciting high-voltage electric discharges using a radiator, and then removing it from the well, different the fact that at least one high-voltage discharge is produced with the simultaneous supply into the interelectrode space of the emitter non-detonating in donapolnennoy exothermic mixture and its combustion at high voltage electrochemical burst with release of gases, vapor and plasma and creating pressures up to 100 MPa and a shock wave, further expanding the hole with soil compaction its walls and filling material hardenable well. 2. The method according to claim 1, characterized in that as a non-detonating water-filled exothermic mixture, a paste containing aluminum powder, nitrate and water is used. 3. The method according to any one of claims 1 and 2, characterized in that, for example, a concrete mixture is used as a hardening material. 4. The method according to any one of claims 1 to 3, characterized in that they produce breakdown-free electrical discharges with a large interelectrode space (20-250 cm), blocked by a tubular cartridge. 5. The method according to any one of claims 1 to 4, characterized in that the high-voltage discharges are produced, at least when the emitter is located on the bottom of the well. 6. The method according to any one of claims 1 to 5, characterized in that the emitter is equipped with a sectioned cartridge for storing and portioning a non-detonating water-filled exothermic mixture during the production of another electrochemical explosion. 7. The method according to any one of claims 1 to 5, characterized in that the emitter is combined with a submersible discharge electric station, which is equipped with a sectioned cartridge for storing and portioning a non-detonating water-filled exothermic mixture, and the station is immersed in the well together with the emitter. 8. The method according to any one of claims 1 to 7, characterized in that after removing the emitter from the well, the reinforcing cage is immersed in the hardening material. 9. The method according to any one of claims 1 to 8, characterized in that prior to immersion of the emitter in the well, a reinforcing cage is attached to it by detachable connection, and before the emitter is removed, it is disconnected from the reinforcing cage, which is left in the well. 10. The method according to any one of claims 1 to 8, characterized in that during the erection of the printed support structure in soils with inclusions of rock, an electric discharge with an electrochemical explosion is produced with the simultaneous destruction of the rock and the formation of an array reinforced with hardening material in the destroyed zone. 11. The method according to any one of claims 1 to 8, characterized in that the emitter is mounted on a hollow rod, and a portion of a non-detonating water-filled exothermic mixture is introduced into the interelectrode space through the rod cavity. 12. The method according to any one of claims 1 to 11, characterized in that the well in the soil is formed by drilling. 13. The method according to any one of claims 1 to 12, characterized in that the well is formed using an inventory casing, the extraction of which is carried out cyclically with the implementation of each cycle before the production of the next high-voltage discharge. 14. The method according to any one of claims 1 to 12, characterized in that the well is formed using a thixotropic solution, mainly bentonite. 15. The method according to any one of claims 1 to 11, characterized in that the well is formed using an inventory casing with a lost tip, after disconnecting which the casing is removed. 16. The method according to any one of claims 1 to 15, characterized in that a pile or cylindrical anchor or truncated cone is erected in the soil, facing up or down with a large base, or a pile or anchor with at least one broadened section along height. 17. The method according to any one of claims 1 to 15, characterized in that in the soil they erect a wall or enclosing structure from adjacent piles or piles with widenings adjacent to each other. 18. The method according to any one of claims 1 to 15, characterized in that a reinforcing soil structure in the form of a pile or anchor with at least one broadened section is erected in the soil. 19. The method according to p. 18, characterized in that the soil reinforcing structure is erected in the body of the embankment with the arrangement of piles and / or anchors in rows and / or tiers, respectively, in width and height of the embankment. 20. The method according to p. 18, characterized in that the reinforcing soil structure is erected in reinforcing soil or soil of natural composition located behind the newly built or reinforced supporting wall, or the wall of the embankment, or the foundation of the bridge, or overpass, or overpass.

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