RU2376428C1 - Multi-storied building and method of erection on slopes or cliffs - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction, namely to multi-storied buildings and methods of their erection on slopes or cliffs. The multi-storied building includes terraces with their slanting parts being connected to rigidly inter-connected horizontal reinforced concrete foundation slabs and load-bearing walls. The said load-bearing walls are made as retaining walls stretching to the height of each building storey and form part of foundation. The foundation is made many-floored, multi-graded and built into slope or cliff. It consists of pile work at each building storey, which is formed by one or more lines of piles erected in the horizontal part of terrace, horizontal reinforced concrete foundation slab and retaining wall to be mounted on pile work so that to form solid reinforced concrete structure as a foundation floor of each storey. The upper parts of retaining walls in each underlying foundation floor are rigidly connected with horizontal reinforced concrete foundation slab of each above-lying floor in the points of their axes crossing and form common any-floored multi-graded structure of solid building foundation. Longitudinal load-bearing walls or framework columns are erected on horizontal reinforced concrete foundation slab of each foundation floor on the same as retaining walls of underlying foundation floor or at some distance from that axis to side of slope or cliff. Reinforced concrete floor slabs are mounted above retaining walls by their one side and on longitudinal load-bearing walls or framework columns by their other side. The floor slabs are rigidly connected with columns and extend with horizontal reinforced concrete foundation slab at each storey. In addition, the aisle length of reinforced concrete floor slabs at each storey, except for the ground floor, is equal to a sum of distances between retaining walls in horizontal projection but no less than two underlying foundation floors so that common closed net volume of the whole building foundation can be produced.

EFFECT: possibility of multi-storied building erection on slope of cliff.

3 cl, 4 dwg

Description

The invention relates to the construction, namely to the construction of a multi-storey building and the method of its construction on a slope or cliff, and can be used in the development of slopes, including steep, or cliffs, including coastal, on which it is planned to erect multi-storey monolithic and prefabricated monolithic buildings, including in zones with seismicity of more than 6 points.

According to the results of patent research in the field of construction of multi-storey buildings, it is clear that the problem of erecting multi-storey buildings on slopes, including on steep slopes, or cliffs, is relevant and not sufficiently resolved not only in Russia, but also abroad.

There is a terrace-type building erected on the slopes according to the copyright certificate No. 1359426, class. E04H 9/02, publ. 12/15/87, bull. No. 46, which includes foundations, supporting structures in the form of continuous arches with protrusions mounted obliquely in the vertical plane, and floor structures, the lower foundations being placed at the mark of the bottom of the slope obliquely to the side of the slope, the upper foundations are placed vertically at the upper mark of the slope.

A disadvantage of the known analogue is its limited technological capabilities, since, firstly, the transfer of concentrated loads from the weight of the entire building by arch systems to relatively small supporting planes, and secondly, it is not possible to strengthen and use the middle section of the slope between the upper and lower foundations.

Known multi-storey building, a structure erected on the slopes, according to copyright certificate No. 1636559, cl. E04H 1/00, publ. 03/23/91, bull. No. 11, which contains a frame of blocks placed along the slope at a distance from each other and interconnected by means of ties. During the construction of the building, the vegetation layer is removed on the planned slope, erecting resistant structures buried in bedrock, installation of gratings, frame structures of the lower blocks is carried out, after which work is underway to erect the bonds that combine all the blocks into a spatial structure.

However, with this analogue, the building is erected by assembling the frame from blocks without the use of engineering protection elements from dangerous slope processes, which does not allow it to be erected on steep slopes subject to landslide processes.

Known building and method of its construction according to the application No. 2003125805, class. EB04 1/34, publ. 2005.03.10, in which the building contains a foundation supporting the building structure mounted on the foundation, hinged fastening elements, flexible vertical rods, which are fixed with their upper ends in the upper part of the supporting building structure and pass through all floors of the building, and the method is characterized in that the whole floor structure is assembled, starting from the top, bottom and raised when assembled to the level of its design position by rotating the support nuts on which this floor is supported, in the process of raising the floor flexible vertical rods are passed through this floor, which, when it is raised to the level of its design position, is pivotally connected to the supporting building structure by means of articulated elements.

A disadvantage of the known analogue is the inability to use the building structure to stabilize the slopes against decompaction, especially in humid climates with frequent heavy rains, in the presence of groundwater, and also for the development of steep slopes and cliffs subject to landslide processes, which generally limits the technological capabilities of the building and the method of its construction.

Closest to the claimed combination of essential features, both structural and technological, and the achieved technical result, is the building according to the copyright certificate No. 1454941, class. E04H 1/00, publ. 01/30/80., Bull. No. 4, which includes foundations, bearing walls with antiseismic belts, hard disks of overlappings, L-shaped rigid rod elements, the vertical part of which in the form of piles is anchored in the ground, the horizontal part is rigidly connected to antiseismic belts, and the method is characterized in that Г- figurative elements, in the form of piles, are installed outside the building at its three outer walls on the slope side and the building itself is made stepped in the direction of the slope.

Similar features with the claimed technical solution, in terms of structural elements, is the presence of a foundation, load-bearing walls, floor slabs, piles, and in terms of the construction method, it is characterized by the fact that the floors of the building are erected stepwise in the direction of the slope from the bottom up.

However, it is impossible to carry out the erection of a multi-storey building on steep slopes or cliffs subject to the effects of dangerous geological slope processes (landslides, landslides, talus), since the construction of foundations and load-bearing walls of a well-known building are not technologically reliable for protection from dangerous slope processes, the size of the anchoring the effect of piles of L-shaped elements located on three sides of the building and beyond, in addition, there are no prismatic spaces in the useful volume of the building va adjacent to the slope of the ground base (termination), and there is no possibility to mechanize the work for installing piles.

The technical task of the invention proposed for patenting is the elimination of these drawbacks, as well as improving the reliability of the building erected on steep slopes and cliffs when exposed to dangerous slope processes and seismic loads, ensuring the stability of the entire slope or cliff, increasing the useful volume of the building and expanding it technological capabilities, ensuring the complete mechanization of work during construction.

The problem is solved by a new set of essential features, allowing to obtain a new useful technical result due to the fact that in the building, including the foundation, load-bearing walls, floor slabs and piles, the new thing is that terraces are made on the slope or precipice, to the slopes of which are rigidly connected between each other are horizontal horizontal reinforced concrete slabs and load-bearing walls, while the latter are made retaining to the height of each floor of the building and are an integral part of the foundation. The foundation is multi-tiered, stepped, built into the slope or precipice and consists on each floor of the building of a pile base formed by one or more rows of piles installed on the horizontal part of the terrace, a horizontal horizontal reinforced concrete slab and retaining wall installed on the pile base in such a way that form a solid reinforced concrete structure in the form of a tier of the foundation of each floor of the building, the upper parts of the retaining walls of each underlying tier of the foundation are rigidly connected to the foundation and horizontal reinforced concrete slabs of each overlying foundation layer at the intersection of their axes and as a whole form a single multi-tiered stepped construction of a monolithic foundation of the entire building, in which the width of the horizontal foundation reinforced concrete slabs and, accordingly, the distance between the retaining walls of the overlying and underlying foundation layers in horizontal projection identical or variable depending on the shape of the slope or cliff. On the foundation horizontal reinforced concrete slabs of each foundation tier on the same axis as the retaining walls of the underlying foundation tier or with some deviation from this axis towards the slope or cliff, longitudinal load-bearing walls or columns of the frame are installed, on top of the retaining walls are one side and on the bearing longitudinal walls or columns reinforced concrete floor slabs are installed on the other side of the frame, which are rigidly connected to them and are a continuation of the foundation of horizontal reinforced concrete slabs at each floor already. The reinforced concrete floor slabs on each floor, except the first, have a span length equal to the sum of the distances in horizontal projection between the retaining walls of at least two underlying tiers of the foundation with the possibility of creating a single enclosed useful volume of the foundation building of the entire building.

In the method of erecting a multi-story building, including step-wise erection of the above-ground part of the building, the underground part of the building is first erected from the upper part of the slope or precipice, while the soil is developed and terraces are made in it, piles are installed to form the pile foundation, with a gradual transition in the direction from top to bottom along a slope or a cliff as the formation of pile foundations, and after completion of the formation of a pile foundation in the lower part of the slope or cliff begin to erect its supervision of the bottom part upward, and on each pile foundation, starting from the pile foundation of the first tier, a horizontal horizontal reinforced concrete foundation slab and retaining wall are installed that are adjacent to the slope of the terrace and along it, which are rigidly connected to each other at the intersection of their axes and form an integral structure in the form of a tier of the foundation of each floor, while the retaining wall of each underlying tier of the foundation is rigidly connected to the foundation horizontal reinforced concrete slab of each overlying tier of fu foundation at the intersection of their axes, and upon completion of the formation of the uppermost foundation tier, form a single multi-tiered stepped construction of a monolithic foundation of the entire building, built into a slope or precipice, then onto horizontal foundation reinforced concrete slabs of each foundation tier and on the same axis as the retaining wall of the underlying foundation or by some deviation from this axis towards the slope or precipice, starting from the first tier of the foundation and ending with the highest tier of the foundation, establish a longitudinal nye-bearing walls or columns frame, as their construction on top of the retaining walls and the longitudinal load-bearing walls or columns of reinforced concrete frame set slabs, starting from the first to the last floor.

Figure 1 - shows the building, a cross section, figure 2 - the foundation of the building, view of the foundation of horizontal reinforced concrete slabs having the same width, view in perspective, figure 3 - the same, view of the foundation of horizontal reinforced concrete slabs having a variable width , a perspective view, FIG. 4 shows a general view of a building in a perspective view.

The building includes tiers 1 of the foundation, reinforced concrete slabs 2 of the floors, retaining walls 3 and longitudinal bearing walls 4 or columns of the frame; to the slope of the terraces, foundation horizontal reinforced concrete slabs 5 and retaining walls 3 are installed, which are made to the height of each floor of the building and are an integral part of the foundation.

The foundation of the building is multi-tiered, stepped, built into a slope or precipice, on each tier 1 the foundation consists of a pile foundation, a horizontal horizontal reinforced concrete slab 5 and a retaining wall 3, which together form a solid reinforced concrete structure in the form of a tier 1 foundation of each floor of the building. The pile foundation is formed by one or several rows of piles 6 installed on the horizontal part of the terraces formed during excavation.

The upper parts of the retaining walls 3 of each underlying tier 1 of the foundation are rigidly connected to the foundation horizontal reinforced concrete slabs 5 of each overlying tier 1 of the foundation at the intersection of their axes and as a whole form a single multi-tiered stepped construction of a monolithic foundation of the entire building. The width of the horizontal horizontal reinforced concrete slabs 5 and, accordingly, the distance between the retaining walls 3 of the overlying and underlying tiers 1 of the foundation in the horizontal projection (in plan) is made the same or variable depending on the shape of the slope or precipice (in Figs. 2 and 3, the arrows are the same and variable distances, in the form B = const or B ≠ const). So, if the slope or cliff slope increases, then the horizontal distance between the vertical retaining walls 3 of the overlying tier 1 and the underlying tier 1 decreases, and if the slope or cliff steepness decreases, then the horizontal projection between the vertical retaining walls 3 of the overlying tier 1 and underlying tier 1 is increasing.

On the horizontal foundation reinforced concrete slabs 5 of each tier 1 of the foundation, on the axis with retaining walls 3 of the underlying tier 1 of the foundation or with some deviation from this axis towards the slope or cliff, longitudinal load-bearing walls 4 or columns of the frame are installed (mounted).

Reinforced concrete slabs 2 of the floors are installed on one side on the retaining walls 3 on the top, the other side mounted on top of the longitudinal bearing walls 4 or columns of the frame, while they are rigidly connected to them and are a continuation of the foundation of horizontal horizontal reinforced concrete slabs 5 on each floor. Reinforced concrete slabs of 2 floors of each floor, except the first, have a span length equal to the sum of the distances in the horizontal projection between the retaining walls of at least two underlying tiers 1 of the foundation, which is optimal for creating a single closed useful volume of the building.

The method of construction of multi-storey buildings is as follows.

Taking into account the number of floors of a building under construction, for example a five-story building, it is planned to break down the slope (precipice) into five terraces in the ground for the construction of five tiers 1 of the building’s foundation. First, from the upper part of the slope or precipice, the underground part of the building is erected, soil is excavated, the uppermost terrace is built and piles 6 are installed (symbolically indicated with one number in the drawing) on the horizontal part of the terrace, thus forming the pile base of the uppermost fifth tier 1 (conventionally marked with one digit) the foundation of the fifth floor of the building, while the arrangement of piles and the arrangement of pile rows, as well as their number, are set depending on the bearing capacity of the slope soil or bryva. Then they descend further down the slope, on the next lower section, develop the soil and make a terrace, install one or several rows of piles 6 and form the pile base of the underlying fourth tier 1 of the foundation of the fourth floor of the building, then go down further down the slope, on the next lower section, develop the soil and perform a terrace, install one or more rows of piles 6 and form a pile base of the underlying third tier 1 of the foundation of the third floor of the building, then go down the slope , in the next lower section, soil development is carried out and a terrace is made, one or several rows of piles 6 are installed and the pile foundation of the second tier 1 of the foundation of the second floor of the building is formed, then they descend down the slope and the soil is excavated at the lowest level and the terrace is installed, one is installed or several rows of piles 6 and form the pile base of the lowest first tier 1 of the foundation of the first floor of the building.

Thus, on the horizontal part of the terraces, rows of piles 6 form the pile foundations of the tiers 1 of the foundations, starting from the top fifth and ending with the bottom first, placed on a slope or cliff successively from top to bottom, respectively, and prepared for the construction of the aerial part of a multi-storey building. After completion of the formation of the pile base in the lower part of the slope or cliff, the construction of its aboveground part begins.

The construction of the aboveground part of the building is carried out in the reverse order, starting from the lower first tier 1 of the foundation, rising up the slope. So, on each pile foundation, starting from the first tier 1 of the foundation, upon completion of construction of which they switch to the second tier, etc., then along the entire slope and close to it on the pile base, a horizontal horizontal reinforced concrete slab 5 and a retaining bearing wall 3 are installed , rigidly connect them together at the intersection of their axes and, as a result, receive, together with the pile base, an integral structure in the form of tier 1 of the foundation of each floor. At the same time, the upper parts of the retaining walls 3 of each underlying tier of the foundation are rigidly connected to the horizontal foundation reinforced concrete slab 5 of each overlying tier of the foundation at the intersection of their axes.

Upon completion of the formation of the uppermost tier 1 of the foundation, they form a single multi-tiered stepped structure of a monolithic foundation of the entire building embedded in a slope or precipice. Then, on top of the horizontal horizontal reinforced concrete slabs 5 on each tier 1 of the foundation and on the same axis as the retaining wall 3 of the underlying tier 1 of the foundation or with some deviation from this axis towards the slope or cliff, starting from the first tier and ending with the fifth tier, install (install ) longitudinal bearing walls 4 or columns of the frame. As the retaining walls 3 and longitudinal bearing walls 4 or carcass columns are erected from above, retaining walls 3 and longitudinal bearing walls 4 or carcass columns are installed on reinforced concrete slabs 2 of the floor, starting from the first to fifth floors, while the sides of the reinforced concrete slabs 2 of the first and second floors the fourth floors facing the tiers 1 of the foundation are rigidly connected to the foundation horizontal reinforced concrete slabs 5, respectively, from the second to the fifth tiers of the foundation. Reinforced concrete slabs 2 of the fifth, last floor of the building, which are slabs of the building cover, are installed on the retaining wall 3 of the fifth tier 1 of the foundation and are also rigidly connected to it, while reinforced concrete slabs of 2 floors, starting from the second to fifth floors, are set by the span equal to the sum of the distances in plan between the retaining walls 3 of at least two underlying tiers 1 of the foundation.

When installing piles 6 on the horizontal part of the terrace, their number and arrangement relative to each other, as well as the distance over which the arrangement of pile rows is carried out, is set depending on the bearing capacity of the slope or cliff soil, which allows you to transfer vertical and horizontal loads to the soil layers while ensuring their necessary bearing capacity for the perception of both vertical and horizontal efforts.

The multi-tier and steppedness of the foundation allows you to evenly distribute the spacer forces from the active soil pressure to the retaining walls 3 and through them to the horizontal horizontal reinforced concrete slabs 5 and piles 6 of all tiers 1 of the foundation, while due to the increased rigidity of the structure, all piles 6 have the same operational load.

The necessary removal of a decompressed and unstable mass of soil during its development and the implementation of terraces before installing piles 6 can reduce the spacer forces on each tier 1 of the foundation.

A multi-storey building erected on a slope or cliff by the claimed method ensures the stability of the slope or cliff from dangerous slope processes, in particular from landslide processes, and seismic effects. The shift of each tier 1 of the foundation and floor of a multi-storey building towards the slope (precipice) helps to reduce the tipping moment during seismic impact with the vector directed away from the cliff, and with the reverse direction of the seismic impact vector only vertical loads on the pile foundations increase, which is not dangerous for an erected multi-story building, since the building, in this case, has higher safety margins.

The combination of new structural elements, as well as new techniques for the construction of the building ensures the suitability of using the inventive multi-storey building as both public and residential, erected on steep slopes or cliffs.

The invention in comparison with the closest analogue and other world analogues in the field of construction of high-rise buildings on slopes or cliffs has increased reliability when used as a public or residential building,

- ensures the stability of the entire cliff or slope as a whole, and also provides advanced technological capabilities:

- the possibility of building a building on steep slopes or cliffs subject to the effects of dangerous geological slope processes (landslides, landslides, talus, etc.), including in areas with increased seismic hazard;

- in the full volume of the building, prismatic spaces are formed adjacent to the soil of the base of the slope or precipice, then this space can be used as an additional useful volume of the building;

- full mechanization of ongoing work on the installation of rows of piles.

Thus, the invention claimed for patenting “a multi-story building and the method of its construction on a slope or cliff” has, according to the applicant, all the criteria inherent in the invention: novelty, inventive step and industrial applicability, i.e. is patentable.

Claims (3)

1. A multi-storey building, including a foundation, load-bearing walls, floor slabs and piles, characterized in that terraces are made on the slope or precipice, to the slopes of which are fixed horizontal concrete reinforced concrete slabs and load-bearing walls, the latter being made retaining to a height each floor of the building are an integral part of the foundation, and the foundation is multi-tiered, stepped, built into a slope or precipice and consists on each floor of the building of a pile foundation formed by one m or several rows of piles installed in the horizontal part of the terrace, horizontal reinforced concrete foundation slab and retaining wall installed on the pile base in such a way that they form a solid reinforced concrete structure in the form of a foundation tier of each floor of the building, the upper parts of the retaining walls of each underlying foundation tier are rigidly connected with horizontal horizontal reinforced concrete slabs of each overlying tier of the foundation at the intersection of their axes and as a whole form a single multi-tiered step-by-step construction of the monolithic foundation of the entire building; longitudinal bearing walls or columns of the frame are installed on the foundation horizontal reinforced concrete slabs of each foundation foundation on the same axis as the retaining walls of the underlying foundation level or with some deviation from this axis towards the slope or cliff, one side on top of the retaining walls and on the longitudinal bearing walls or columns of the carcass, the other side has reinforced concrete floor slabs that are rigidly connected to them and are a continuation of horizontal horizontal reinforced concrete slabs on each floor, and reinforced concrete floor slabs on each floor, except the first, have a span length equal to the sum of the distances in the horizontal projection between the retaining walls of at least two underlying tiers of the foundation with the possibility of creating a single closed useful volume of the foundation building of the entire building. 2. The building according to claim 1, characterized in that the width of the horizontal foundation of reinforced concrete slabs and, accordingly, the distance between the retaining walls of the overlying and underlying tiers of the foundation in horizontal projection are made the same or variable depending on the shape of the slope or cliff. 3. A method of erecting a multi-story building on a slope or cliff, including stepwise erection of the aboveground part of the building from the bottom up, characterized in that the underground part of the building is first erected from the top of the slope or cliff, the soil is developed, terraces are made in it, and piles are installed for the formation of the pile foundation, with a gradual transition in the direction from top to bottom along the slope or precipice as the formation of pile foundations, and after completion of the formation of the pile foundation in the lower part of the slope or a precipice, they begin to erect its aerial parts from the bottom up, while on each pile foundation, starting from the pile foundation of the first tier, a horizontal horizontal reinforced concrete slab and retaining wall are installed that are adjacent to and along the terrace slope, with a horizontal horizontal reinforced concrete slab and retaining the wall is rigidly connected to each other at the intersection of their axes and form a solid structure in the form of a tier of the foundation of each floor, while the retaining wall of each underlying tier fu the dement is rigidly connected to the horizontal horizontal reinforced concrete slab of each overlying foundation tier at the point of intersection of their axes, and upon completion of the formation of the uppermost foundation tier, they form a single multi-tiered stepped construction of a monolithic foundation of the entire building, built into a slope or precipice, then onto horizontal horizontal reinforced concrete slabs of each tier foundation and on the same axis with the retaining wall of the underlying tier of the foundation or some deviation from this axis towards the slope or gaps, starting from the first tier of the foundation and ending with the uppermost tier of the foundation, establish longitudinal load-bearing walls or columns of the carcass, as they are erected on top of retaining walls and on longitudinal load-bearing walls or columns of the carcass, reinforced concrete slabs are installed, starting from the first to the last floor.

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