BG64261B1 - Antiseismic support for a building - Google Patents

Abstract

The invention shall find application in the construction of buildings in areas subject to seismic effects, as well as for building of structures for which there is a need for the isolation of any dynamic effects. Any oversizing is avoided and a chance is offered for creating vibration absorption in a wide range. The structural part can be replaced, as it is independent from the structure of the support which comprises a top structure (1), having a damping part fitted under it, and a supporting block. The lower supporting block is in the form of a foundation pit (2) of water impermeable surface (3), constructed in a soil base (4), the walls (6) of which form an obtuse angle to the bottom (5). The damping part is in the form of a fluid (7) fitted in the foundation pit (2). The top structure (1) has a common fundamental part (9) which has positive floatability, it is found in the fluid and includes beams (13, 24) fitted in radiated form. According to an embodiment, in the area of the bottom (5) there is a plastic flexible coating (14) with perforation (15), enabling the fluid (7) to get through in the zone between wall (6) of the foundation pit (2) and the coating (14), and in addition, part (16) of it is maintained in operating position, practically vertical, by means of a system of floats (17). The upper end of the flexible coating (14) is fixed along its length on the ground base (4), and parallel to this fixing, on base (4), there is a groove (19) machined, connected by canals (20) to the interior of the fluid (7), behind the flexible cover (14), forming a circumferential chamber (21). 6 claims, 6 figures

Description

(54) ANTI-SEISMIC BUILDING SUPPORT

Technical area

The invention relates to a seismic support for a building that will find application in the construction of buildings in areas exposed to earthquakes, as well as in the construction of facilities that need to be isolated from dynamic impacts.

BACKGROUND OF THE INVENTION

There is a known anti-seismic support for a building, which includes a top structure located below it a damping part and a lower support block. The lower support block is a pit with a watertight surface formed in the ground, with the bottom and walls of the basin being formed. The damping part is a fluid located in the pit. The upper structure is rigidly connected to the building, a common foundation, watertight and positively buoyant, located in the fluid. Between the common foundation part and the earth base are located in at least two groups - upper and lower - spring elements, connected rigidly to the walls of the pit. There are a number of centering strips adjacent to the common base part, forming at least two webs spaced above each other, covering the common base part [1].

With the known support, there is a significant technological difficulty in forming the networks of spring elements, especially in the construction of the building, in order to form the intended connection between the building part and the networks, which leads to the cost of construction. In case of seismic impact, the lower support block has a much higher flexibility than the top structure, which means that its elements should be resized to absorb high seismic loads, which increases material consumption and low seismic efficiency. . Ie the construction is complex and not sufficiently effective for the costs that would be incurred in constructing it.

It is an object of the invention to provide an anti-seismic support for a building that allows the absorption of earthquake forces, avoiding the resizing of its elements, and the efficient absorption of wide-range vibrations.

The problem is solved with an anti-seismic support for a building, which includes a top structure located below it a damping part and a lower support block. The lower support block is a pit with a watertight surface formed in the ground, with the bottom and walls of the pit formed. The damping part is a fluid located in the pit. The upper structure is a rigidly connected building with a common foundation, which is watertight and positively buoyant and located in the fluid. Between the common foundation part and the earth base there are springing elements connected rigidly to the walls of the pit. According to the invention, the common foundation includes beamed beams, and the pit has surrounding walls at an obtuse angle to the bottom.

According to one embodiment, a plastic flexible coating is placed in the ditch, on which the fluid is arranged, and in the bottom region the plastic flexible coating has a perforation allowing the fluid to pass in the area between the wall of the ditch and the plastic flexible coating. In this part of the flexible coating is maintained in a working position approximately vertical by a float system. The upper end of the flexible cover is fixed lengthwise on the ground. In parallel to this fixation, there is a groove formed on the ground base, connected through channels with the interior of the fluid behind the flexible coating forming the annular chamber. In this case, the plastic flexible surface has a surface larger than the surface of the pit, the part of which, located between the float system and the fixing point of the upper edge of the coating, is normally folded in normal operating condition. The float system is fixed to the pit by horizontal and vertical elastic connections

It is recommended that the common foundation portion be a flat beam-reinforced element with the board facing up.

According to another embodiment, the common base portion is formed by supporting beams, at the outer ends of which there are vertical bars pointing downwards. Each of these vertical bars is enclosed by a positively buoyant cup element. Moreover, each vertical rod is supported at the bottom of the cup element and immediately below its upper edge, and the cup elements are arranged in the fluid.

The cup elements may have an elliptical cross section for increased stability.

It is appropriate for the common base part to have additional anti-wind connections fixed to the ground.

The advantages of the anti-seismic support according to the invention lie in the ability to absorb earthquake forces, avoiding the resizing of its elements, allowing the effective absorption of wide-range vibrations due to the slope of the walls of the pit, to the performance of the common foundation part , as well as the internal vibration damping through the flexible coating used. In the presence of seismic activity, the support always holds and returns to its horizontal position the construction, with the cost of construction and maintenance of the building in operational condition is significantly reduced compared to the known support. The building part itself can be replaced and is independent of the anti-seismic supports, which may also be used in any other type of building located on them.

Explanation of the figures

The invention is illustrated by an exemplary embodiment, explained by the accompanying figures, of which:

Figure 1 is a vertical section through a building with an antisismic support according to the invention;

Figure 2 is a view from AA of Figure 1; 3 is a vertical sectional view through a building having an antisismic support according to an embodiment of the invention;

4 is a vertical sectional view through a building with an antisismic support according to an embodiment of the invention;

FIG. 5 is a BB view of FIG. 3; FIG. 6 is a sectional view along the BB of FIG. 5.

Examples of carrying out the invention

The anti-seismic support for a building according to the embodiments includes a top structure 1 located below it a damping part and a lower support block. The lower support block is a ditch 2 with a watertight surface 3 formed in the ground 4. The surface 3 of the ditch may be of cast concrete, cement, plastics or other suitable form, with bottom 5 and walls 6 of the ditch 2 being formed. The damping part is fluid 7 located in the ditch 2. The top structure 1 is rigidly connected to the building 8 common base part 9 with a positive buoyancy and is located in the fluid 7. Between the common base part 9 and the walls 6 of the ditch 2, horizontal however, at least three springing elements 10 are located. These springing elements 10 are intended to absorb the horizontal component of earthquake impacts and, under normal operational condition of the building, to absorb wind forces acting on it. The spring elements 10 are rigidly connected to the walls 6 of the pit 2. According to the invention, in order to achieve a good load-bearing capacity and to effectively extinguish vibrations in an earthquake, the common foundation part 9 includes beam-shaped beams 13, 24, and the pit 2 has surrounding walls 6, applied at a blunt angle to the bottom 5, which provides better attenuation of seismic waves.

Typically, the common foundation portion 9 is a flat, reinforced with beams 13 element 11 of suitable building material, for example, reinforced concrete, metal and the like, with a board 12 pointing upwards.

According to a variant embodiment of the support in the ditch 2 is spread plastic flexible coating 14, on which is placed the fluid 7. This plastic flexible coating 14 has a perforation 15 in the area of the bottom 5, allowing the passage of fluid 7 in the area between the wall 6 of the ditch 2 and the plastic flexible coating 14. In this case, the flexible coating part 14 is kept in a working position approximately vertical by a system of floats 17 that can be replaced at depreciation. The upper end 18 of the flexible cover 14 is fixed lengthwise on the earth base 4. In parallel to this fixation, on the earth base 4, there is a shaped groove 19 connected through channels 20 to the interior of the fluid 7 behind the flexible cover 14 forming a circular chamber 21. The plastic flexible cover 14 has a surface larger than the surface of the pit 2, the portion thereof located between the float system 17 and the fixing position 18 at the upper edge of the cover 14, in normal operating condition, is freely folded. The float system 17 is fixed to the ditch 2 by horizontal 2 and vertical elastic connections 23. In this embodiment, the common base part 9 has additional anti-wind connections 31 fixed to the earth base 4, taking on the usual horizontal, for example wind, loads in service. .

In another embodiment, the common base portion 9 is a support beam 24, at the outer edges 25 of which there are vertical bars 26 pointing downwards. Each vertical bar 26 is enclosed by a positively buoyant cup 27. The vertical rod 26 has a bearing 29 placed at the bottom 28 of the cup element 27 and immediately below its upper edge 30. The cup elements 27 are arranged in fluid 7. It is appropriate for the cup elements 27 to have an elliptical cross section, as shown in FIG. , which avoids the use of springing elements to absorb the horizontal component of the seismic forces.

Typically, in this embodiment, the common foundation portion 9 also has additional anti-wind connections 31 fixed to the earth base 4, which absorb the usual horizontal loads in service.

Usually the dimensions of the ditch are smaller than those of the building in plan. The connection between the building 8 and the ground base 4 is made by a transition element of the type of ladder or ramp fixed with the possibility of sliding on at least one side - from the ground base or the building. Preferably the fluid 7 used is water, which significantly reduces the cost of maintaining the serviceability of the support according to the invention.

Application of the invention

The invention is applicable to the construction of buildings and other structures which are to be isolated from dynamic impacts. It can be used for single building or for the design of neighborhoods, mainly from small buildings - single-family dwellings, commercial buildings and more.

The construction of the anti-seismic support for buildings is carried out by first constructing the pit and completing all adjacent facilities, depending on the chosen embodiment of the invention. The building itself is prepared as a single billet of suitable for the climate of the ^rayo-: Material and fixed on the total ^fundamen-: damentna part 9 which can be with implementing 'on according to the aforementioned embodiments. It is also possible to construct the * building on site, on the already constructed common foundation part 9, according to the chosen embodiment of the invention, whereby temporary strengthening of the site or filling of the pit after completion of the building should be used.

The action of the anti-seismic support according to the invention is as follows.

In the case of seismic impact, the vertical component is absorbed by the fluid 7 (water) and transformed into waves that dampen the initial impact due to the difference in the medium in which they are transmitted, as well as the different depth of the pit due to the inclination of its walls. Horizontal spring elements 10 are included as auxiliary effects, while the upper structure 1 remains in relative rest or moves smoothly, preventing disturbance of the integrity of the building 8.

When the design of the ditch is with a duplicate plastic flexible cover 14, the damping is also due to the formation of a annular chamber 21 between the walls 6 of the ditch 2 and the plastic flexible coating 14. In this case, in the case of seismic impact, the vertical component pushes water upwards, which blows freely upwards. part at the ends of the flexible cover 14, thereby absorbing some of the earthquake energy. The water collected in this part is directed downwards and guided by the fixed ends 18 of the coating 14, fills the groove 19. One part of the fluid 7 is directed against the part above it and extinguishes its energy, and the other part passes through the channels and forms an additional stream which reduces the impact of the earthquake force. In this case, the flexible coating moves as a membrane to the main fluid 7 in the pit and further dampens the seismic wave.

In the other embodiment, the damping of the oscillations arising from seismic impact is obtained both from their transmission in the fluid-specific medium 7 and from the intended shape of the cup-like elements 27, which have different orientation of the axes of the elliptical section, such as part of the impact energy is accumulated by the rotation of these cup-shaped members 27 by the support of vertical bars 26. Generally, the building 8 supported on the common base part 9 receives slight deviations from the volume your usual position.

Claims (6)

Claims 1. Anti-seismic support for a building comprising a top structure, below it a damping part and a lower support block, the lower support block being a pit with a watertight surface formed in a ground base, the bottom and walls of the pit are formed, and the damping part is a fluid located in the ditch, wherein the upper structure is a rigidly connected building with a common base part, which is watertight and with positive buoyancy and is located in the fluid, such as between the common base h ast and the earth base are springing elements connected rigidly to the walls of the pit, characterized in that the common base part (9) includes a beam of various spaced beams (13, 24), and the pit (2) has surrounding walls (6) located at a blunt angle to the bottom (5). 2. An anti-seismic support for a building according to claim 1, characterized in that a plastic flexible coating (14) is housed in the pit (2) on which the fluid (7) is located, such as in the bottom region (5) the plastic flexible coating (14) has a perforation (15) allowing the fluid (7) to pass in the area between the wall (6) of the pit (2) and the plastic flexible coating (14), with the flexible coating part (16) being maintained in a working position approximately vertical by a float system (17), the upper end (18) of the flexible covering (14) is fixed lengthwise on the earth base (4), and parallel to this fixation, on the earth base (4), there is a shaped groove (19) connected through channels (20) to the interior of the fluid (7) , behind the flexible coating (14) forming the annular chamber (21), wherein the plastic flexible coating (14) has a surface larger than the surface of the pit (2) and the portion thereof located between the float system (17) and the fixing point (18) at the upper edge of the coating (14), in normal operating condition, is freely folded, with the float system (17) is fixed to the ditch (2) by horizontal (22) and vertical elastic connections (23). An anti-seismic support according to claim 1 or 2, characterized in that the common base part (9) is a flat beam (13) element (11) with an edge (12) pointing upwards. Anti-seismic support according to claim 1, characterized in that the common base part (9) represents beams (13) which are supporting beams (24), at the outer ends (25) of which there are vertical bars (26) directed downwards, each of which has vertical bars (26) enclosed by a positively buoyant cup element (27), each vertical bar (26) having a bearing (29) disposed at the bottom (28) of the cup element (27) and immediately below its upper edge (30) and the cup-shaped elements (27) are arranged in the fluid (7). An anti-seismic support according to claim 4, characterized in that the cup elements (27) have an elliptical cross section. An anti-seismic support according to any one of claims 2 to 5, characterized in that the common base part (9) has additional anti-wind connections (31) fixed to the ground (4). Attachment: 6 figures Literature 1. US 3748 800.