RU2807350C1 - Constructive and technological solution for foundation of intermediate support of high pile work type constructed in temporary enclosing structure - Google Patents

Abstract

FIELD: bridge construction.

SUBSTANCE: invention relates to the construction of supports for bridges and hydraulic structures erected in the waters of rivers, lakes, seas and reservoirs. The foundation of the intermediate support contains support body 2, having a foundation and an underwater part; at least one pile 3; grillage 1, supported by at least one pile 3 and configured to distribute the load from piles 3. When constructing the foundation of the intermediate support, temporary enclosing structure 5 is provided, containing a temporary cylindrical shell assembled from metal segmented panels. The segmented shield of temporary cylindrical shell 5 consists of at least one curved deck sheet, and on the outer side the deck sheet is reinforced with a system of longitudinal and transverse ribs and a flange with holes for bolted connections is provided along the contour of the deck. Temporary cylindrical shell 5 is immersed in the ground by an amount that exceeds the value of local erosion. The foundation contains cement pad 4, and the space between the bottom of cement pad 4 and mark 8 of the bottom of the reservoir inside temporary cylindrical shell 5 is filled with inert material. A method for constructing the foundation of an intermediate support is also proposed.

EFFECT: reducing the material intensity of the process of constructing the foundation of an intermediate support.

13 cl, 2 dwg

Description

Field of technology to which the invention relates

The invention relates to bridge construction and can be used in the construction and reconstruction of supports for bridges and hydraulic structures erected in the waters of rivers, lakes, seas and reservoirs.

State of the art

Various design and technological solutions for supports of bridges and hydraulic structures erected in water bodies of water characterized by significant depth in the area where the supports are installed, as well as methods for constructing such supports, are known in the state of the art. In particular, when constructing supports in water bodies of considerable depth, various temporary enclosing structures can be used, designed with the possibility, in particular, of eliminating water inflow into the pit in which the support is being constructed. In general, the scientific and technical literature and regulatory and technical documentation describe the following main types of temporary enclosing structures for the construction of supports in the water area:

- sheet pile fencing;

- bottomless box;

- a box with a bottom.

Despite the fact that sheet piling barriers are widely used in bridge construction practice, they are characterized by the following disadvantages.

Firstly, sheet pile fencing is characterized by high metal consumption. This is explained by the fact that sheet piling, as a rule, has a rectangular outline, which is why the structure of the fence experiences forces mainly from bending moments, which entails an increase in the profiles of sheet piles and the need to install several tiers of spacer fastenings.

Making the sheet piling cylindrical in plan does not reduce the problem of material consumption, since the coaxial transmission of the compressive annular force in the lock is not ensured. There are many examples of cylindrical sheet piles (cylindrical cofferdams, fenders, etc.), but they are a cylinder filled with inert material, and the sheet pile locks absorb tensile stresses. At the same time, to create a cylindrical sheet piling, a high standard of work is required, ensuring the necessary accuracy of driving individual sheet piles.

The presence of rocky or semi-rocky soils at shallow depths from the bottom level leads to the need for additional work, such as leader drilling (preliminary or performed during immersion). Increased profiles of sheet piles with a significant length of the pile element lead to the need to use more powerful, and therefore heavier equipment, which, in turn, leads to the need to use lifting structures with a large load capacity and reinforced foundations for them.

On the other hand, structures such as “bottomless box” or “boxes with a bottom” are also characterized by high metal consumption and require significant resources (including time) for their assembly. In addition, such structures must be delivered afloat and installed in the design position, which adds complexity to the construction of such structures and increases the cost of material resources for their construction.

RF patent No. 2303674 discloses a method for constructing pile foundations for bridge supports, which includes the formation of at least one vertical support and inclined supports with a slope of their axes relative to the vertical axis equal to 1: (10-12); wells, which are performed by inclined drilling to the full depth in a casing pipe immersed in the ground, followed by installation of a reinforcement cage placed in the casing pipe and supply of concrete mixture when removing the casing pipe. In the known method, a pile is initially constructed vertically located in the center of the grillage contour or a pile offset from the center of the grillage contour in plan along the central axis to one side of the grillage. Then the outermost inclined piles are constructed, each of which is offset from it in plan diagonally to the opposite side of the grillage, which is constructed in the sheet piling. After constructing the grillage, the spaces between the sheet piling and the body of the grillage are filled with soil, and the sheet piling is dismantled after installation on these bridge supports of the span. The known solution makes it possible to create pile foundations for bridge supports of high load-bearing capacity and reliability using technology that reduces the consumption of concrete and metal by 20-30%.

The disadvantages of this known solution include the limited use of technology associated with the impossibility of its use in the presence of soils at the base that do not allow the immersion of sheet piles without additional measures, as well as a significant increase in metal consumption for sheet piling at excavation depths of more than 6-7 meters, with In this case, this solution reduces the number of rotations of the sheet pile at the construction site, which leads to significant additional costs during the construction of the support foundation.

Disclosure of the Invention

The technical problem solved by the present invention is the high complexity and resource intensity (in particular, material intensity) of constructing foundations for intermediate supports of bridges and hydraulic structures using methods known from the prior art.

The problem solved by the invention is to create a method for constructing a foundation for an intermediate support and, accordingly, a foundation for an intermediate support, in which the design of the foundation is linked to the organizational and technological diagram of its construction and the temporary enclosing structure used.

The technical result achieved when using the claimed invention is to reduce the material intensity of the process of constructing the foundation of an intermediate support. In particular, it ensures a reduction in the material consumption of the temporary enclosing structure, which is necessary for the construction of the foundation and underwater part of the body of the support of a bridge or hydraulic structure, and optimization of the lifting equipment necessary for the installation of the foundation of the intermediate support, as well as a reduction in labor costs and time for installation and dismantling of the temporary enclosing structure construction of a pit during the construction of the foundation of an intermediate support. In addition, the performance of the intermediate support foundation structure at the operational stage against the action of wave and ice loads is improved.

The problem is solved by the fact that the design of the foundation and underwater parts of the support body, as well as the design of the temporary enclosing structure, have an essentially cylindrical shape.

In one aspect, the problem is solved by the foundation of an intermediate support of bridges and hydraulic structures, containing: a support body having a foundation and underwater parts; at least one pile; a grillage supported on at least one pile and configured to distribute the load from the piles. In this case, the foundation differs in that during the construction of the foundation of the intermediate support, the construction of a temporary enclosing structure is provided, containing a temporary cylindrical shell assembled from metal segmental panels; the segmental shield of the temporary cylindrical shell consists of at least one curved deck sheet, and on the outer side the deck sheet is reinforced with a system of longitudinal and transverse ribs, and a flange with holes for bolted connections is provided along the contour of the deck; the temporary cylindrical shell is immersed in the ground by an amount that exceeds the value of local erosion; the foundation additionally contains a cement pad, and the space between the bottom of the cement pad and the level of the bottom of the reservoir inside the temporary cylindrical shell, if necessary, can be filled with inert material.

The grillage may have a shape selected from the group containing a cylinder or a square or rectangle inscribed in a circle of the required radius. In one or more embodiments, to make it possible to remove the shell, a layer of adhesive waterproofing is glued to the segment shield between the deck sheet of the temporary cylindrical shell and the concrete of the backfill pad. The segmental shield of the lower tier of a temporary enclosing structure may have a knife part, which is a deck sheet extended below the lower flange with additional reinforcement with overhead sheets and vertical triangular ribs. In one or more embodiments, the design of the foundation and underwater part of the support body is cylindrical in shape. In one or more embodiments, the metal shields are made of steel. In one or more embodiments, the bottom portion of the temporary cylindrical shell is covered with rock material or lined with sandbags. The inert material is selected from the group containing sand and crushed stone. A waterstop can be built into the joint of the lower section of the deck sheet that falls into the area where the grouting pad is laid.

In the second aspect, the problem is solved by a method for constructing a foundation for an intermediate support of bridges and hydraulic structures, comprising the steps of: installing one or more piles extending below the bottom level and preferably into the ground; install a structure of a temporary enclosing structure containing a temporary cylindrical shell from segmental panels in such a way that the temporary cylindrical shell is immersed in the ground below the bottom mark by an amount that covers the value of local erosion; carry out laying of the cement pad within the temporary cylindrical shell; create a grillage resting on said one or more piles, combining the heads of one or more piles, on top of the cement pad within the temporary cylindrical shell; install the support body on top of the grillage; and dismantle the structure of the temporary enclosing structure.

In one or more embodiments, water is pumped from the space surrounded by the assembled temporary cylindrical shell. If necessary, cover the lower part of the temporary cylindrical shell with stone material or line it with sandbags. If necessary, a waterstop is built into the joint of the lower section of the temporary cylindrical shell, which falls into the area where the cement pad is laid. In one or more embodiments, a layer of adhesive waterproofing is glued onto the deck sheet of the segmental shield using a temporary cylindrical shell before laying the backfill pad.

Brief description of drawings

Drawings are provided herein to facilitate understanding of the present invention. They are schematic and not to scale. The drawings are intended solely for the purpose of illustrating the essence of the proposed invention and not to define or limit the scope of its legal protection.

In FIG. 1 shows a schematic diagram of the design of the foundation of an intermediate support according to the invention;

In FIG. Figure 2 shows a schematic diagram of a segmental shield design for a temporary cylindrical shell.

Carrying out the invention

In general, the construction of a foundation of the “high pile grillage” type includes pile elements (bored, drilled, driven, etc.), united by a grillage located below the water level, as well as the design of a temporary enclosing structure for construction work grillage In one or more embodiments of the invention, the design of a temporary enclosing structure and the design of the foundation and underwater part of the support body are made in a cylindrical shape (in other embodiments of the invention, it is also possible to construct a support grillage in the form of a square or rectangle inscribed in a circle of the required radius).

According to the invention, the foundation of an intermediate support for bridges and hydraulic structures contains the following main elements: a support body having a foundation and an underwater part; at least one pile; a grillage supported on at least one pile and configured to distribute the load from the piles.

In FIG. Figure 1 schematically illustrates the design of the intermediate support foundation. Position 1 shows the grillage. Position 2 shows the body of the support. Position 3 generally shows piles. Position 4 shows the cement pad. Position 5 generally shows the design of a temporary enclosing structure. Position 6 shows the calculated water level at the site of construction of the intermediate support foundation. Position 8 shows the bottom mark at the site where the foundation of the intermediate support will be erected. Position 9 shows the thickness of the soil under the layer of soft soil at the bottom of the reservoir at the site of construction of the foundation of the intermediate support. It should be noted that in FIG. 1 illustrates the foundations of two intermediate supports as an illustrative practical example, however, such a number of elements is not required and it should be understood that at least one support may be constructed in various embodiments. The number of supports does not limit the scope of legal protection of the claimed invention.

The distinctive features of the claimed invention include, in particular, the fact that during the construction of the foundation of the intermediate support, a structure 5 of a temporary enclosing structure is provided, containing a temporary cylindrical shell assembled from segmental panels. The temporary cylindrical shell is immersed in the ground below mark 8 of the bottom by an amount that exceeds the value of local erosion.

In addition, the distinctive features of the claimed invention include the fact that the foundation of the intermediate support contains a grouting pad 4 under the grillage 1, which is designed to prevent water inflow into the pit formed by the temporary cylindrical shell of the structure 5 of the temporary enclosing structure lowered to the bottom under the grillage being constructed, and the grouting pad 4 has a thickness determined by calculation, based on the depth of the pit and the adhesion of the cement pad to the piles. The space between the bottom of the cement pad 4 and the reservoir bottom mark 8 within the temporary cylindrical shell is preferably filled with an inert material (such as, by way of non-limiting example, sand, crushed stone and the like). The presence or absence of inert material under the cement pad 4 is determined individually when designing the support.

To reduce adhesion (for example, to make it possible to remove the temporary cylindrical shell using jacks) between the deck sheet of the temporary cylindrical shell and the concrete of the backfill pad 4, a layer of waterproofing can be glued to the deck sheet. To ensure that water does not break through the cement pad 4 along the contact boundary “temporary cylindrical shell - cement filling” into the joint of the lower section of the temporary cylindrical shell falling into the area where the cement pad 4 is laid, in one or more embodiments of the invention a waterstop is built in. As a non-limiting example, the waterstop can be made in the form of a rubber sealing profile, the two ends of which are rigidly embedded in the abutting structures, for example, one end can be embedded in the joint of segment panels when assembling the shell, and the other end can be embedded in the backfill pad 4 when it is assembled. concreting.

To prevent the removal of concrete from the cement pad 4 from under the knife bottom section of the temporary cylindrical shell formed around the lower part of the temporary cylindrical shell by local erosion when concreting the cement pad 4, the following technological measures are provided:

- immersion of the temporary cylindrical shell of the temporary enclosing structure into the ground below level 8 of the bottom by an amount that exceeds the value of local erosion, calculated in advance based on the hydrological parameters of the reservoir during the period of work;

- sprinkling with stone material or lining with sandbags the lower part of the temporary cylindrical shell to prevent local erosion directly at the structure of the temporary cylindrical shell.

In FIG. Figure 2 schematically illustrates a segmental panel design of a temporary cylindrical shell. Position 11 denotes the deck sheet, position 12 denotes longitudinal ribs, position 13 denotes transverse ribs, position 14 denotes flanges with holes for bolted connections of segment panels. Position 10 indicates the inner side of the segment shield. Deck sheet 11 is bent radially. The specific parameters of the deck sheet 11 are selected from the conditions of work on the construction of the grillage (such as the diameter of the grillage or the circle described around the grillage and the required technological clearance for the installation of formwork and scaffolding). On the outside, the deck sheet 11 is reinforced with a system of longitudinal ribs 12 and transverse ribs 13, which are attached to the deck sheet 11 by welding. Along the contour of the deck sheet 11, which forms the segment shield, there are flanges 14 with holes for bolting the segment shields to each other. A segmental shield can be made of metal, for example steel. Suitable steel grades are determined when designing a temporary cylindrical shell and are assigned based on the calculation of the temporary cylindrical shell and the climatic region of the construction of the support using the proposed technology.

The design 5 of the temporary enclosing structure with the indicated forms of the grillage 1 is carried out according to the “bottomless box” principle, but with significant differences.

Firstly, a significant difference in the design of a temporary enclosing structure is its cylindrical shape in plan, due to which the structure experiences forces primarily from compressive forces that are transmitted through the flange joints between the segmental panels of the temporary enclosing structure. Preferably, segmental panels are prefabricated in a factory before the construction of a temporary enclosing structure.

Factory production of segmental shields allows for the transmission of force on the flanges 14 along the axes of the longitudinal ribs 12 and transverse ribs 13, as well as the deck sheet 11 of the temporary cylindrical shell, which, in turn, leads to significant savings in material. So, for example, in the prior art, if a sheet piling fence made from L5-UM sheet piling according to TU 24107-008-00186269-2021 is used as a structure for a temporary enclosing structure, the metal consumption for the sheet piling wall will be 225 kg per square meter of the sheet piling perimeter (when using a tubular sheet piling ShTS-1020x10-ZSG1 according to TU 5264-014-01393674-2012 – 241.4 kg/ ^m2 ) without taking into account the mass of the spacer fastening.

At the same time, when using a temporary cylindrical shell of similar dimensions from segmental panels in accordance with the invention, the consumption will be 140~160 kg per square meter of fence perimeter. At the same time, taking into account the minimum penetration of the protective shell into the ground below mark 8 of the bottom of the reservoir, which does not depend on the calculation of the depth of the minimum embedment in the ground, the savings on the total metal consumption will be even greater.

Reducing the metal consumption of the structure 5 of the temporary enclosing structure leads to the minimization of lifting equipment, and the absence of embedding in the ground (for example, in the ground 9) eliminates the need for equipment for immersion (vibratory hammers, hydraulic hammers, etc.).

When carrying out work on the construction of the foundation of an intermediate support in accordance with the invention, an important task is to eliminate the ovality of the temporary cylindrical shell. This is achieved by precision manufacturing of the segmental panels and quality control of the assembly before the entire temporary cylindrical shell is lowered into the designed position on site.

The use of segmental panels with flanges 14 with holes for bolting allows for enlarged assembly in any location, as a non-limiting example - in the immediate vicinity of the construction site of the intermediate support foundation or in advance at a temporary work site or on the deck of a barge. Installation of the temporary cylindrical shell is possible either in its entirety, subject to the availability of a lifting structure with the required lifting capacity and with the required lifting height, or by section-by-section installation of enlarged rings of the containment shell, followed by lowering using the “heavy-lifting” method (using hydraulic jacks).

In one or more embodiments, the segmental shield of the lower tier of the temporary cylindrical shell has a knife part, which is a deck sheet 11 extended below the lower flange 14, with additional reinforcement with overlay sheets and vertical triangular ribs. This facilitates the deepening of the lower tier of the temporary cylindrical shell into the soil layer below mark 8 of the bottom to prevent water inflow into the pit formed by the temporary cylindrical shell of the structure 5 of the temporary enclosing structure lowered to the bottom under the grillage being constructed.

In the second aspect of the present invention, a method for constructing an intermediate support foundation for bridges and hydraulic structures is proposed, the result of which is an intermediate support foundation according to the first aspect described above. A method for constructing an intermediate support foundation in one or more embodiments of the invention comprises at least the following steps.

For each intermediate support, one or more piles are installed (preferably in the form of a “pile bush” of several piles). This can be accomplished in a variety of ways well known in the art. In particular, piles can be, without limitation, drilled (reinforced concrete), bored, drilled, drilled, drilled, driven, pressed, with or without casing, etc. Piles can be installed either substantially vertically or at various angles other than vertical. The piles pass below the bottom mark 8 and to a certain depth into the ground 9.

The structure 5 of the temporary enclosing structure, which is based on a temporary cylindrical shell, is assembled from segment panels, preferably made in advance, in such a way that the temporary cylindrical shell is immersed in the ground below mark 8 of the bottom by an amount that covers the local erosion value calculated in advance based on hydrological parameters reservoir during the period of work. Installation of the structure 5 of the temporary enclosing structure from segmental panels can be carried out by assembling the structure directly at the site of construction of the intermediate support foundation or by at least partially pre-assembling the structure in another place, for example on a temporary work site or on the deck of a barge. The segment panels are connected to each other by bolting flanges 14 with holes for bolting. As a result of connecting all the segmental panels of at least one tier of the structure 5 of the temporary enclosing structure, a cylindrical shape in plan is ensured. To deepen the lower tier of the temporary cylindrical shell into the soil layer below mark 8 of the bottom by an amount that covers the value of local erosion, the segmental shield of the lower tier of the temporary cylindrical shell preferably has a knife part described above, which facilitates the immersion of the lower tier into the soil layer.

If necessary, water is then pumped out from the space surrounded by the assembled temporary cylindrical shell. Also, if necessary, the lower part of the temporary cylindrical shell is covered with stone material or covered with sandbags to prevent local erosion directly at the structure of the temporary cylindrical shell.

The laying of the backfill pad 4 is carried out, as a non-limiting example, by pouring concrete into the lower part of the temporary enclosing structure, to the level of the bottom of the foundation slab. The scope of legal protection of the invention is not limited to this method of laying the cement pad 4, and it is obvious to specialists in this field of technology that it is possible to use other methods for creating a cement pad. For example, an anti-seepage curtain, arranged by jet grouting of the soil, can be used as a cement pad 4.

In one or more embodiments of the invention, to ensure that water does not break through the cement pad 4 along the contact boundary “temporary cylindrical shell - cement pad”, a waterstop is additionally built into the joint of the lower section of the temporary cylindrical shell falling into the area where the cement cushion 4 is laid. If necessary, to reduce adhesion between the deck sheet 11 of the temporary cylindrical shell and the concrete of the backfill pad 4, for example, to ensure the possibility of subsequent removal of the temporary cylindrical shell, in some embodiments of the method, a layer of adhesive waterproofing is glued to the deck sheet 11 before laying the backfill pad 4. Between grillage 1 and the inner surface of the temporary cylindrical shell there is space for formwork and passage.

Upon completion of laying the backfill pad 4, a grillage 1 is created, resting on the mentioned one or more piles (or on a “pile bush”), combining the heads of the piles and configured to distribute the load from the load-bearing elements of the intermediate support being built. As a non-limiting example, a grillage is created by pouring concrete (if necessary, using reinforcement) inside a temporary cylindrical shell to a certain height above the backfill pad 4, and this height may, as a non-limiting example, not exceed the design water level 6.

Support body 2 is installed on grillage 1. In one or more non-limiting embodiments of the invention, the support body 2 may have a thickness (diameter) less than the thickness (diameter) of the backfill pad 4. The support body 2 can be made monolithic (concrete is poured into the formwork) or prefabricated monolithic. In the latter case, contour (cladding) reinforced concrete blocks included in the support structure serve as formwork.

Upon completion of the above stages, the structure of the temporary enclosing structure is dismantled. This stage may include lifting the structure of the temporary enclosing structure in whole or in part, disassembling the temporary cylindrical shell into segmental panels, etc. Moreover, after disassembly, the temporary cylindrical shell can be reassembled and reused in the construction of the next intermediate support foundation or other structure of a bridge or other hydraulic structure.

It should be noted that the above method steps do not necessarily have to be performed exactly and only in the above order. Some of the above steps of the method according to the invention may be performed simultaneously, or in an order different from the order in which they are described above.

What is new in the proposed invention is that the design of the foundation of the intermediate support and the temporary cylindrical shell are initially designed as a single organizational and technological solution, which makes it possible to achieve maximum effect during construction (reducing construction time, reducing the metal consumption of the structure, and economic efficiency). The circular outline of the foundation (and, if necessary, the support body of a bridge or hydraulic structure) and the design of a temporary enclosing structure, which is based on a temporary cylindrical shell, allows minimizing the costs (physical and time) of the design of a temporary enclosing structure during the construction stage, and also improve the performance of the main structure of the foundation of the intermediate support at the operational stage under the influence of wave and ice loads. The cylindrical shape in terms of the foundation of the intermediate support is optimal from the point of view of the perception of ice and wave loads, since when the direction of influence of ice and wave loads changes, the cross section of the support subject to this influence does not change, unlike other possible shapes (rectangular, square, etc. .).

It should be noted that, as described above, a temporary cylindrical shell is installed around the support foundation and serves to protect the pit from water. The closer the shape (in plan) of the shell is to the shape of the foundation, the more rational the entire system of the temporary enclosing structure will be, which leads to a reduction in the material consumption of the structure (in particular, by minimizing the consumption of concrete for the backfill pad and metal for the construction of the temporary cylindrical shell). Also, due to the approach of the plan form (and, as a consequence, dimensions) of the temporary cylindrical shell to the plan form of the foundation of the intermediate support, the narrowing of the reservoir bed for the period of work is minimized (which in practice happens, for example, on rivers when work is carried out simultaneously on a large number of supports ) or narrowing of the shipping clearance.

From the above it follows that the foundation of the support, which is being constructed under the protection of a temporary cylindrical shell, must rationally fit into a circle (ideally it is the shape of a circle, but it can also be a square or a polygon inscribed in a circle).

Those skilled in the art will recognize possible specific embodiments other than those described above, which are also within the scope of legal protection of the present invention. The above details of the implementation of the foundation of the intermediate support and the method of its construction do not limit the scope of legal protection of the invention, which is determined only by the following claims and its equivalents.

Claims (28)

1. The foundation of the intermediate support of bridges and hydraulic structures, containing: a support body having a foundation and underwater parts; at least one pile; a grillage supported on at least one pile and configured to distribute the load from the piles; characterized in that: the design of the foundation and underwater parts of the support body are cylindrical in shape; when constructing the foundation of the intermediate support, a temporary enclosing structure is provided, containing a temporary cylindrical shell assembled from metal segmental panels; the segmental shield of the temporary cylindrical shell consists of at least one curved deck sheet, and on the outer side the deck sheet is reinforced with a system of longitudinal and transverse ribs, and a flange with holes for bolted connections is provided along the contour of the deck; the temporary cylindrical shell is immersed in the ground by an amount that exceeds the value of local erosion; the foundation additionally contains a cement pad, and the space between the bottom of the cement pad and the level of the bottom of the reservoir inside the temporary cylindrical shell is filled with inert material. 2. The foundation according to claim 1, in which the grillage has a shape selected from the group containing a cylinder, or a square, or a rectangle inscribed in a circle of the required radius. 3. The foundation according to claim 1, in which, to make it possible to remove the shell, a layer of adhesive waterproofing is glued between the deck sheet of the temporary cylindrical shell and the concrete of the backfill pad onto the segmental shield. 4. The foundation according to claim 1, in which the segmental shield of the lower tier of the temporary enclosing structure has a knife part, which is a deck sheet extended below the lower flange, with additional reinforcement with overhead sheets and vertical triangular ribs. 5. The foundation according to claim 1, in which the metal panels are made of steel. 6. The foundation according to claim 1, in which the lower part of the temporary cylindrical shell is sprinkled with stone material or lined with sandbags. 7. The foundation according to claim 1, in which the inert material is selected from the group containing sand and crushed stone. 8. The foundation according to claim 1, in which a waterstop is built into the joint of the lower section of the deck sheet that falls into the area where the grouting pad is laid. 9. A method for constructing a foundation for an intermediate support of bridges and hydraulic structures, containing stages in which: install one or more piles extending below the bottom mark and preferably into the ground; install a structure of a temporary enclosing structure containing a temporary cylindrical shell from segmental panels in such a way that the temporary cylindrical shell is immersed in the ground below the bottom mark by an amount that covers the value of local erosion; carry out laying of the cement pad within the temporary cylindrical shell; create a grillage resting on said one or more piles, combining the heads of one or more piles, on top of the cement pad within the temporary cylindrical shell; install the support body on top of the grillage, and the design of the foundation and underwater parts of the support body have a cylindrical shape; And dismantling the structure of the temporary enclosing structure. 10. The method according to claim 9, further comprising the step of pumping out water from the space surrounded by the assembled temporary cylindrical shell. 11. The method according to claim 9, further comprising the step of covering the lower part of the temporary cylindrical shell with stone material or lining with sandbags. 12. The method according to claim 9, further comprising the step of embedding a waterstop into the joint of the lower section of the temporary cylindrical shell, which falls into the area where the backfill pad is laid. 13. The method according to claim 9, further comprising the step of gluing a layer of adhesive waterproofing onto the deck sheet of the segmental shield of the temporary cylindrical shell before laying the backfill pad.